TWI652550B - Exposure method and exposure apparatus, and component manufacturing method - Google Patents
Exposure method and exposure apparatus, and component manufacturing method Download PDFInfo
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- TWI652550B TWI652550B TW106113430A TW106113430A TWI652550B TW I652550 B TWI652550 B TW I652550B TW 106113430 A TW106113430 A TW 106113430A TW 106113430 A TW106113430 A TW 106113430A TW I652550 B TWI652550 B TW I652550B
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01B—MEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
- G01B11/00—Measuring arrangements characterised by the use of optical techniques
- G01B11/26—Measuring arrangements characterised by the use of optical techniques for measuring angles or tapers; for testing the alignment of axes
- G01B11/27—Measuring arrangements characterised by the use of optical techniques for measuring angles or tapers; for testing the alignment of axes for testing the alignment of axes
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- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
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- G03F9/00—Registration or positioning of originals, masks, frames, photographic sheets or textured or patterned surfaces, e.g. automatically
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- G03F9/70—Registration or positioning of originals, masks, frames, photographic sheets or textured or patterned surfaces, e.g. automatically for microlithography
- G03F9/7003—Alignment type or strategy, e.g. leveling, global alignment
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/02—Manufacture or treatment of semiconductor devices or of parts thereof
- H01L21/027—Making masks on semiconductor bodies for further photolithographic processing not provided for in group H01L21/18 or H01L21/34
- H01L21/0271—Making masks on semiconductor bodies for further photolithographic processing not provided for in group H01L21/18 or H01L21/34 comprising organic layers
- H01L21/0273—Making masks on semiconductor bodies for further photolithographic processing not provided for in group H01L21/18 or H01L21/34 comprising organic layers characterised by the treatment of photoresist layers
- H01L21/0274—Photolithographic processes
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/67—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere
- H01L21/68—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere for positioning, orientation or alignment
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L21/00—Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
- H01L21/67—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere
- H01L21/68—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere for positioning, orientation or alignment
- H01L21/681—Apparatus specially adapted for handling semiconductor or electric solid state devices during manufacture or treatment thereof; Apparatus specially adapted for handling wafers during manufacture or treatment of semiconductor or electric solid state devices or components ; Apparatus not specifically provided for elsewhere for positioning, orientation or alignment using optical controlling means
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/49—Method of mechanical manufacture
- Y10T29/49002—Electrical device making
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- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Engineering & Computer Science (AREA)
- Condensed Matter Physics & Semiconductors (AREA)
- Manufacturing & Machinery (AREA)
- Computer Hardware Design (AREA)
- Microelectronics & Electronic Packaging (AREA)
- Power Engineering (AREA)
- Health & Medical Sciences (AREA)
- Chemical Kinetics & Catalysis (AREA)
- Chemical & Material Sciences (AREA)
- Environmental & Geological Engineering (AREA)
- Epidemiology (AREA)
- Public Health (AREA)
- Exposure And Positioning Against Photoresist Photosensitive Materials (AREA)
- Container, Conveyance, Adherence, Positioning, Of Wafer (AREA)
- Length Measuring Devices By Optical Means (AREA)
- Theoretical Computer Science (AREA)
- Exposure Of Semiconductors, Excluding Electron Or Ion Beam Exposure (AREA)
- General Engineering & Computer Science (AREA)
Abstract
本發明,係根據在載台(WST1)上搭載之四個讀頭(601~604)中、包含互異之一個讀頭之三個讀頭所屬之第1讀頭群與第2讀頭群中所含之讀頭對向於標尺板上對應區域之區域(A0)內,使用第1讀頭群所得之位置資訊驅動載台(WST1),並使用以第1及第2讀頭群所得之位置資訊求出對應之第1及第2基準座標系(C1、C2)間之偏差(位置、旋轉、定標之偏差)。使用該結果修正使用第2讀頭群所得之測量結果,據以修正第1及第2基準座標系(C1、C2)間之偏差、以及四個讀頭(601~604)之分別對向之標尺板上之區域彼此間之偏差伴隨之測量誤差。 The present invention is based on the first read group and the second read of three read heads including three read heads which are different from each other among the four read heads (60 1 to 60 4 ) mounted on the stage (WST1). In the area (A 0 ) of the read head included in the head group facing the corresponding area on the ruler plate, the position information (WST1) driven by the first read head group is used to drive the stage (WST1). The position information obtained by the head group is used to find the deviations (position, rotation, and calibration deviations) between the corresponding first and second reference coordinate systems (C 1 , C 2 ). Use this result to correct the measurement results obtained by using the second read head group to correct the deviations between the first and second reference coordinate systems (C 1 , C 2 ) and the four read heads (60 1 to 60 4 ). The measurement error is accompanied by the deviation of the areas on the opposite ruler plates from each other.
Description
本發明係關於曝光方法及曝光裝置、以及元件製造方法,特別是關於在製造半導體元件等微元件(電子元件)之微影製程所使用之曝光方法及曝光裝置、以及使用前述曝光方法或曝光裝置之元件製造方法。 The present invention relates to an exposure method, an exposure device, and a device manufacturing method, and more particularly, to an exposure method and an exposure device used in a lithography process for manufacturing micro-devices (electronic components) such as semiconductor devices, and using the aforementioned exposure method or exposure device Device manufacturing method.
一直以來,於製造半導體元件(積體電路等)、液晶顯示元件等電子元件(微元件)之微影製程,主要係使用步進重複(step & repeat)方式之投影曝光裝置(所謂之步進機)、或步進掃描(step & scan)方式之投影曝光裝置(所謂之掃描步進機(亦稱為掃描機))等。 In the past, the lithography process for manufacturing semiconductor components (integrated circuits, etc.) and electronic components (micro-components) such as liquid crystal display elements has mainly been a projection exposure device using the step & repeat method (the so-called stepping). Machine), or a step & scan projection exposure device (a so-called scanning stepper (also called a scanner)).
此種曝光裝置,隨著半導體元件高積體化之元件圖案微細化,日漸被要求要具有高重疊精度(位置對準精度)。因此,形成有圖案之晶圓或玻璃板等基板之位置測量亦被要求更高之精度。 Such an exposure device is increasingly required to have a high overlap accuracy (positional alignment accuracy) with the miniaturization of an element pattern of a semiconductor device that is highly integrated. Therefore, the position measurement of substrates such as patterned wafers or glass plates is also required to have higher accuracy.
作為回應此種要求之裝置,例如專利文獻1中揭示了一種具備位置測量系統之曝光裝置,此位置測量系統係使用搭載在基板台上之複數個編碼器型感測器(編碼器讀頭)。此曝光裝置中,編碼器讀頭係藉由對與基板台對向配置之標尺照射測量光束、並接受來自標尺之返回光束據以測量基板台之位置。專利文獻1等所揭示之位置測量系統中,標尺最好是能盡可能的涵蓋除了投影光學系正下方區域外之基板台之移動區域。因此,雖有大面積之標尺需要,但欲以高精度製作大面積之標尺不僅非常困難且成本亦 高。因此,一般係製作複數個將標尺分割為複數個部分之小面積標尺,並將之加以組合。因此,雖然希望複數個標尺間之位置對準能正確進行,但現實上,但欲消除各體之製造誤差及無誤差的加以組合,皆是非常困難的。 As a device responding to such a request, for example, Patent Document 1 discloses an exposure device having a position measurement system. This position measurement system uses a plurality of encoder-type sensors (encoder read heads) mounted on a substrate stage. . In this exposure device, the encoder read head measures the position of the substrate table by irradiating the measuring beam with a ruler disposed opposite to the substrate table, and receiving the return beam from the ruler. In the position measurement system disclosed in Patent Document 1, etc., it is preferable that the scale can cover the moving area of the substrate stage except the area directly below the projection optical system as much as possible. Therefore, although a large area scale is required, it is not only very difficult and costly to make a large area scale with high accuracy high. Therefore, generally, a plurality of small-area scales that divide the scale into a plurality of sections are made and combined. Therefore, although it is hoped that the position alignment between a plurality of scales can be performed correctly, in reality, it is very difficult to eliminate the manufacturing error of each body and the combination without error.
[先行技術文獻] [Advanced technical literature]
[專利文獻1]美國專利申請公開第2006/0227309號說明書 [Patent Document 1] US Patent Application Publication No. 2006/0227309
本發明係在上述情形下完成者,其第1態樣之第1曝光方法,係使物體曝光,其包含:包含設於沿既定平面移動之移動體之複數個讀頭中、至少一個互異之讀頭之複數個讀頭分別所屬之複數個讀頭群,在該移動體外部與該既定平面略平行配置之測量面上之對應區域分別對向之該移動體之第1移動區域內,求出分別對應該複數個讀頭群之複數個不同基準座標系間之偏差之修正資訊之動作;以及在該第1移動區域內,使用屬於該複數個讀頭群之各讀頭群之複數個讀頭求出該移動體之位置資訊,使用該位置資訊與和該複數個讀頭群之各讀頭群對應之複數個不同基準座標系間之偏差之該修正資訊驅動該移動體,以使保持於該移動體之物體曝光之動作。 The present invention is completed under the above circumstances, and the first exposure method of the first aspect is to expose an object, which includes: at least one of a plurality of read heads including a plurality of read heads provided on a moving body moving along a predetermined plane; Of the plurality of read heads of the read heads respectively belong to a plurality of read head groups, and the corresponding areas on the measuring surface outside the moving body arranged slightly parallel to the predetermined plane are respectively opposed to the first moving area of the moving body, An operation of obtaining correction information corresponding to deviations between a plurality of different reference coordinate systems of the plurality of read head groups; and using the complex number of each read head group belonging to the plurality of read head groups in the first movement area The reading heads obtain the position information of the moving body, and use the correction information of the deviation between the position information and a plurality of different reference coordinate systems corresponding to each reading head group of the plurality of reading head groups to drive the moving body to The action of exposing an object held by the moving body.
根據此方法,即能在不受與複數個讀頭群之各個對應之複數個不同基準座標系間之偏差之影響,使用與複數個讀頭群之各個對應之複數個讀頭求出之移動體之位置資訊,在第1移動區域內以良好精度驅動移動體,進而對該移動體所保持之物體進行高精度之曝光。 According to this method, it is possible to use the movement obtained by the plurality of read heads corresponding to each of the plurality of read head groups without being affected by the deviation between the plurality of different reference coordinate systems corresponding to each of the plurality of read head groups. The position information of the body drives the moving body with good accuracy in the first moving area, and then exposes the object held by the moving body with high accuracy.
本發明第2態樣之第2曝光方法,係使物體曝光,其包含:為使該物體曝光,根據在保持該物體之移動體上搭載之第1數之讀頭中、分別屬於包含互異之一個讀頭之第1讀頭群與第2讀頭群之第2數之讀頭在與測量面上對應之區域對向之既定區域內,使用該第1、第2讀頭群所得之第1、第2位置資訊之至少一方驅動該移動體之動作。 The second exposure method according to the second aspect of the present invention is to expose an object, which includes: in order to expose the object, according to the first number of reading heads mounted on a moving body holding the object, each of them includes a difference. The first read head group of the first read head group and the second read head number of the second read head group are in a predetermined area opposite to the area corresponding to the measurement surface, and the first and second read head groups are used. At least one of the first and second position information drives the movement of the mobile body.
根據此方法,即使與第1讀頭、第2讀頭對應之座標系不同,亦能不受其影響而高精度的驅動移動體。 According to this method, even if the coordinate systems corresponding to the first read head and the second read head are different, the moving body can be driven with high accuracy without being affected by the coordinate system.
本發明第3態樣之第1曝光裝置,係使物體曝光:其具備:移動體,係保持物體沿既定平面移動;位置測量系,係根據設於該移動體之複數個讀頭中、對在對該物體之曝光位置近旁於該移動體外部配置成與該既定平面略平行之測量面照射測量光束並接收來自該測量面之返回光束之讀頭之輸出,求出該移動體之位置資訊;以及控制系,根據以該位置測量系取得之該位置資訊驅動該移動體,並視該移動體之位置從該複數個讀頭中切換該位置測量系用以取得該位置資訊之讀頭;該控制系係在該複數個讀頭對向於該測量面之該移動體之第1移動區域內,修正對應該複數個讀頭之複數個基準座標系彼此間之偏差。 The first exposure device according to the third aspect of the present invention exposes an object: it includes: a moving body that keeps the object moving along a predetermined plane; a position measurement system that is based on a plurality of read heads provided on the moving body. Near the exposure position of the object, near the outside of the moving body, a measuring surface that is arranged slightly parallel to the predetermined plane irradiates the measuring beam and receives the output of the read head returning the light beam from the measuring surface to obtain the position information of the moving body. ; And a control system that drives the mobile body based on the position information obtained by the position measurement system, and switches the position measurement system to obtain the position information read head from the plurality of read heads according to the position of the mobile body; The control system corrects deviations between the reference coordinate systems corresponding to the plurality of read heads in a first moving area of the plurality of read heads facing the moving body of the measurement surface.
根據此裝置,由於複數個基準座標系彼此間之偏差受到修正,因此可使用複數個讀頭高精度測量移動體之位置資訊,進行驅動(位置控制)。 According to this device, since the deviations between the plurality of reference coordinate systems are corrected, it is possible to use a plurality of read heads to measure the position information of the moving body with high accuracy and drive (position control).
本發明第4態樣之第2曝光裝置,係使物體曝光,其具備:移動體,係保持物體沿既定平面移動;位置測量系,係根據搭載於該移動體上之第1數之讀頭中、對在對該物體之曝光位置近旁於該移動體外部配置成與該既定平面略平行之測量面照射測量光束並接收來自該測量面之返回光束之讀頭之輸出,求出該移動體之位置資訊;驅動該移動體之驅動系;以及控制系,係根據該位置測量系之第1數之讀頭中、包含互異之一個讀頭之第1讀頭群與第2讀頭群分別所屬之第2數之讀頭與測量面上對應區域對向之既定區域內,使用該第1、第2讀頭群所得之第1、第2位置資訊之至少一方,控制該驅動系。 The second exposure device according to the fourth aspect of the present invention exposes an object and includes: a moving body that keeps the object moving along a predetermined plane; and a position measurement system based on the first reading head mounted on the moving body Middle, irradiate the measuring beam with a measuring beam arranged near the exposure position of the object to the outside of the moving body, which is slightly parallel to the predetermined plane, and receive the output of the read head returning beam from the measuring surface, to find the moving body Position information; a drive system for driving the moving body; and a control system based on the first reading head group and the second reading head group among the first reading heads according to the position measuring system The drive system is controlled by using at least one of the first and second position information obtained by the first and second read head groups in a predetermined area where the corresponding second read head and the corresponding area on the measurement surface face each other.
根據此裝置,即使與第1讀頭、第2讀頭對應之座標系不同,亦能不受其影響而高精度的驅動移動體。 According to this device, even if the coordinate systems corresponding to the first read head and the second read head are different, the moving body can be driven with high accuracy without being affected by the coordinate system.
本發明第5態樣之第3曝光裝置,係使物體曝光,其具備:移動體, 係保持物體沿既定平面移動;位置測量系,係根據設於該移動體之複數個讀頭中、對在對該物體之曝光位置近旁於該移動體外部配置成與該既定平面略平行之測量面照射測量光束並接收來自該測量面之返回光束之讀頭之輸出,求出該移動體之位置資訊;以及控制系,係根據該位置測量系取得之該位置資訊驅動該移動體,並在能以較用於該移動體位置控制之第1數之讀頭數多之第2數之讀頭測量位置之區域內移動該移動體,以取得藉該位置測量系求出之該移動體之位置資訊之修正資訊。 A third exposure apparatus according to a fifth aspect of the present invention exposes an object and includes: a moving body, Is to keep the object moving along a predetermined plane; position measurement is based on a plurality of read heads provided on the moving body, which are measured near the exposure position of the object and arranged outside the moving body to be slightly parallel to the predetermined plane The surface is irradiated with the measurement beam and receives the output of the read head returning the beam from the measurement surface to obtain the position information of the mobile body; and the control system is to drive the mobile body based on the position information obtained by the position measurement system, and The moving body can be moved within the area of the second reading head measurement position which is more than the first reading head number used for the position control of the moving body to obtain the moving body obtained by the position measurement system. Correction information for location information.
根據此裝置,由於以控制系取得由位置測量系求出之前述移動體之位置資訊之修正資訊,因此可使用該修正資訊以高精度驅動移動體。 According to this device, since the correction information of the position information of the aforementioned mobile body obtained by the position measurement system is obtained by the control system, the correction information can be used to drive the mobile body with high accuracy.
本發明第6態樣之第3曝光方法,係使物體曝光,其包含:在設於沿既定平面移動之移動體之複數個讀頭中、至少包含一個互異讀頭之該移動體位置控制所須之第1數之讀頭分別所屬之複數個讀頭群,與在該移動體外部配置成與該既定平面略平行之測量面對向之該移動體之第1移動區域內移動該移動體,以取得藉由該位置測量系求出之該移動體之位置資訊之修正資訊之動作;以及使用該修正資訊驅動該移動體,以使該移動體所保持之物體曝光之動作。 A third exposure method according to a sixth aspect of the present invention is to expose an object, and the position control station of the moving body includes a plurality of reading heads provided on a moving body moving along a predetermined plane, and at least one of the reading heads is different. The plurality of read head groups to which the first read head of the whisker belongs respectively move the mobile body within the first movement area of the mobile body facing the measurement surface arranged outside the mobile body to be slightly parallel to the predetermined plane. To obtain the correction information of the position information of the moving body obtained by the position measurement; and to use the correction information to drive the moving body to expose the object held by the moving body.
根據此方法,可進行對物體之高精度曝光。 According to this method, high-precision exposure of an object can be performed.
本發明第7態樣之第4曝光裝置,係使物體曝光,其具備:移動體,係保持物體沿既定平面移動;位置測量系,係根據設於該移動體之複數個讀頭中、對在對該物體之曝光位置近旁於該移動體外部配置成與該既定平面略平行之複數個標尺板所構成之測量面照射測量光束並接收來自該測量面之返回光束之讀頭之輸出,求出該移動體之位置資訊;以及控制系,係根據以該位置測量系取得之該位置資訊驅動該移動體,並視該移動體之位置從該複數個讀頭中切換該位置測量系用於該位置資訊之取得之讀頭;該控制系係在該複數個讀頭對向於該測量面之該移動體之第1移動區域內, 取得對應該複數個讀頭之複數個標尺板彼此之位置關係。 The fourth exposure device of the seventh aspect of the present invention exposes an object, and includes: a moving body that keeps the object moving along a predetermined plane; and a position measurement system based on a plurality of reading heads provided in the moving body. A measurement surface composed of a plurality of ruler plates arranged near the exposure position of the object and arranged approximately parallel to the predetermined plane on the outside of the moving body irradiates the measurement beam and receives the output of the read head returning the beam from the measurement surface. The position information of the moving body; and the control system, which drives the moving body according to the position information obtained by the position measuring system, and switches the position measuring system from the plurality of read heads according to the position of the moving body for The read head for obtaining the position information; the control is in the first moving area of the plurality of read heads facing the moving body of the measuring surface, The positional relationship between the plurality of scale plates corresponding to the plurality of read heads is obtained.
根據此裝置,由於以控制系取得複數個標尺彼此之位置關係,因此能使用複數個讀頭高精度測量移動體之位置資訊,進行驅動(位置控制)。 According to this device, since the positional relationship between a plurality of scales is obtained by the control system, it is possible to measure the position information of a moving body with a plurality of read heads and drive (position control) with high accuracy.
本發明第8態樣之第4曝光方法,係使物體曝光,其包含:在設於沿既定平面移動之移動體之複數個讀頭中、包含至少一個相異讀頭之複數個讀頭分別所屬之複數個讀頭群,分別對向於在該移動體外部配置成與該既定平面略平行之複數個標尺板所構成之測量面之該移動體之第1移動區域內,取得分別對應該複數個讀頭群之複數個標尺板彼此之位置關係之動作;在該第1移動區域內,使用屬於該複數個讀頭群之各個之複數個讀頭求出該移動體之位置資訊,使用該位置資訊與對應該複數個讀頭群之各個之複數個標尺板彼此之位置關係驅動該移動體,以使該移動體所保持之物體曝光之動作。 The fourth exposure method of the eighth aspect of the present invention is to expose an object, which includes: among a plurality of read heads provided on a moving body moving along a predetermined plane, a plurality of read heads including at least one distinct read head respectively The plurality of read head groups respectively obtain the corresponding plural numbers in the first moving area of the moving body facing the measuring surface formed by a plurality of ruler plates arranged outside the moving body to be slightly parallel to the predetermined plane. Action of the positional relationship of a plurality of scale plates of each read head group; within the first moving area, using the plurality of read heads belonging to each of the plurality of read head groups to obtain the position information of the moving body, using the The positional relationship between the position information and the plurality of scale plates corresponding to each of the plurality of read head groups drives the moving body to expose the object held by the moving body.
根據此方法,即能不受對應複數個讀頭群之各個之複數個標尺板彼此之位置攀附之影響,使用屬於複數個讀頭群之各個之複數個讀頭求出之移動體之位置資訊,於第1移動區域內以良好精度驅動移動體,進而能進行對該移動體所保持之物體之高精度曝光。 According to this method, it is possible to use the position information of the mobile body obtained by the plurality of read heads belonging to each of the plurality of read head groups without being affected by the position attachment of each of the plurality of scale plates corresponding to each of the plurality of read head groups. In the first moving area, the moving body is driven with good accuracy, and then the high-precision exposure of the object held by the moving body can be performed.
本發明第9態樣之元件製造方法,其包含:使用本發明第1~第4曝光裝置之任一者使物體曝光,以於該物體上形成圖案之動作;以及使形成有該圖案之物體顯影之動作。 A ninth aspect of the present invention is a method for manufacturing a component, which comprises: using any one of the first to fourth exposure devices of the present invention to expose an object to form a pattern on the object; and making the object on which the pattern is formed Development action.
本發明第10態樣之元件製造方法,其包含:使用本發明第1~第5曝光方法中之任一者於物體上形成圖案之動作;以及使形成有該圖案之該物體顯影之動作。 A tenth aspect of the present invention is a method for manufacturing a device, which includes the operation of forming a pattern on an object using any of the first to fifth exposure methods of the present invention, and the operation of developing the object on which the pattern is formed.
10‧‧‧照明系 10‧‧‧ Department of Lighting
11‧‧‧標線片載台驅動系 11‧‧‧ reticle stage drive system
12‧‧‧載台基座 12‧‧‧ Carrier base
13A、13B‧‧‧標線片對準系 13A, 13B‧‧‧ reticle alignment system
14a‧‧‧線圈 14a‧‧‧coil
15‧‧‧移動鏡 15‧‧‧mobile mirror
16‧‧‧標線片干涉儀 16‧‧‧ reticle interferometer
18‧‧‧晶圓干涉儀系統 18‧‧‧ Wafer Interferometer System
20‧‧‧主控制裝置 20‧‧‧Main control device
21、22‧‧‧標尺板 21, 22‧‧‧ Ruler board
211~214‧‧‧標尺板21之4個部分 21 1 ~ 21 4 ‧‧‧ 4 parts of ruler plate 21
221~224‧‧‧標尺板22之4個部分 22 1 ~ 22 4 ‧‧‧ 4 parts of the scale plate 22
21a、22a‧‧‧開口 21a, 22a‧‧‧ opening
27‧‧‧晶圓載台驅動系 27‧‧‧ Wafer Stage Drive System
30‧‧‧平面馬達 30‧‧‧plane motor
40‧‧‧鏡筒 40‧‧‧ lens barrel
50‧‧‧晶圓載台裝置 50‧‧‧ Wafer stage device
601~604‧‧‧編碼器讀頭 60 1 ~ 60 4 ‧‧‧Encoder read head
70、71‧‧‧編碼器系統 70, 71‧‧‧ encoder system
701~704、711~714‧‧‧二維編碼器 70 1 ~ 70 4 , 71 1 ~ 71 4 ‧‧‧Two-dimensional encoder
91‧‧‧載台本體 91‧‧‧the carrier body
91a‧‧‧滑件部 91a‧‧‧Sliding Department
100‧‧‧曝光裝置 100‧‧‧ exposure device
A0~A4‧‧‧測量區域 A 0 ~ A 4 ‧‧‧Measurement area
ALG‧‧‧對準系 ALG‧‧‧ alignment system
AX‧‧‧光軸 AX‧‧‧ Optical axis
C1~C4‧‧‧第1~第4基準座標系 C 1 ~ C 4 ‧‧‧The first to fourth reference coordinate system
CO‧‧‧十字形區域 C O ‧‧‧Cross-shaped area
CA、CE‧‧‧統合座標系 C A , C E ‧‧‧ Integrated Coordinate System
FM1、FM2‧‧‧第1、第2基準標記板 FM1, FM2‧‧‧ first and second fiducial marker plates
IA‧‧‧曝光區域 IA‧‧‧Exposure area
IAR‧‧‧照明區域 IAR‧‧‧lighting area
IL‧‧‧照明光(曝光用光) IL‧‧‧illuminating light (light for exposure)
O1~O4‧‧‧原點 O 1 ~ O 4 ‧‧‧ origin
P‧‧‧曝光中心 P‧‧‧Exposure Center
PL‧‧‧投影光學系 PL‧‧‧ Projection Optics
PU‧‧‧投影單元 PU‧‧‧ Projection Unit
R‧‧‧標線片 R‧‧‧ reticle
RG‧‧‧二維繞射光柵 RG‧‧‧Two-dimensional diffraction grating
RST‧‧‧標線片載台 RST‧‧‧Reticle Stage
W‧‧‧晶圓 W‧‧‧ Wafer
WTB1、WTB2‧‧‧晶圓台 WTB1, WTB2‧‧‧wafer table
WST1、WST2‧‧‧晶圓載台 WST1, WST2‧‧‧wafer stage
圖1係概略顯示一實施形態之曝光裝置之構成的圖。 FIG. 1 is a diagram schematically showing a configuration of an exposure apparatus according to an embodiment.
圖2係顯示配置在投影光學系周圍之編碼器系統之構成的圖。 FIG. 2 is a diagram showing a configuration of an encoder system arranged around a projection optical system.
圖3係顯示配置在對準系周圍之編碼器系統之構成的圖。 Fig. 3 is a diagram showing the configuration of an encoder system arranged around an alignment system.
圖4係將晶圓載台之一部分加以剖斷的放大圖。 FIG. 4 is an enlarged view of a part of a wafer stage.
圖5係顯示晶圓載台上之編碼器讀頭之配置的圖。 FIG. 5 is a diagram showing the configuration of an encoder read head on a wafer stage.
圖6係顯示圖1之曝光裝置中與載台控制相關聯之控制系之主要構成的方塊圖。 FIG. 6 is a block diagram showing a main configuration of a control system associated with stage control in the exposure apparatus of FIG. 1. FIG.
圖7(A)係顯示編碼器讀頭及標尺板之配置與編碼器系統之測量區域間之關係的圖、圖7(B)係顯示與標尺板對向之編碼器讀頭之四個組對應規定之四個載台座標系的圖、圖7(C)係顯示標尺板之四個部分彼此有偏差之情形的圖。 Fig. 7 (A) is a diagram showing the relationship between the configuration of the encoder reading head and the scale plate and the measurement area of the encoder system, and Fig. 7 (B) is the four groups showing the encoder reading head facing the scale plate The figure corresponding to the predetermined four-stage coordinate system, and FIG. 7 (C) is a diagram showing a situation where the four parts of the scale plate are deviated from each other.
圖8(A)、圖8(C)及圖8(E)係顯示在為校正載台座標之載台位置測量中之晶圓載台之動作的圖(其1、2及3)、圖8(B)、圖8(D)及圖8(F)係用以說明四個載台座標系之校正的圖(其1、2及3)。 8 (A), 8 (C), and 8 (E) are diagrams (1, 2 and 3) showing the operation of the wafer stage in the stage position measurement for correcting the stage coordinates, FIG. 8 (B), FIG. 8 (D), and FIG. 8 (F) are diagrams (1, 2 and 3) for explaining the correction of the four coordinate systems of the stage.
圖9(A)及圖9(B)係用以說明統合載台座標系CE之原點、旋轉、定標之測量的圖。 FIG. 9 (A) and FIG. 9 (B) for explaining the origin based integration stage coordinate system C E, the rotation of a given measurement scale of FIG.
圖10(A)及圖10(B)係用以說明統合載台座標系CA之原點、旋轉、定標之測量的圖。 FIG 10 (A) and FIG. 10 (B) for explaining the origin based integration stage coordinate system C A of rotation, a given measurement scale of FIG.
以下,根據圖1~圖10(B)說明本發明之一實施形態。 Hereinafter, one embodiment of the present invention will be described with reference to FIGS. 1 to 10 (B).
圖1中顯示了一實施形態之曝光裝置100之概略構成。曝光裝置100係步進掃描方式之投影曝光裝置、亦即、係所謂的掃描機。如後所述,本實施形態中設有投影光學系PL,以下,係設與投影光學系PL之光軸AX平行之方向為Z軸方向、在與此正交之面內相對掃描標線片與晶圓之方向為Y軸方向、與Z軸及Y軸正交之方向為X軸方向,並設繞X軸、Y軸 及Z軸之旋轉(傾斜)方向分別為θx、θy及θz方向來進行說明。 FIG. 1 shows a schematic configuration of an exposure apparatus 100 according to an embodiment. The exposure device 100 is a projection exposure device of a step-and-scan method, that is, a so-called scanner. As will be described later, the projection optical system PL is provided in this embodiment. Hereinafter, the direction parallel to the optical axis AX of the projection optical system PL is the Z-axis direction, and the reticle is relatively scanned in a plane orthogonal to this. The direction perpendicular to the wafer is the Y-axis direction, and the direction orthogonal to the Z-axis and the Y-axis is the X-axis direction. The directions of rotation (tilt) of the Z-axis and the Z-axis are θx, θy, and θz directions, respectively.
曝光裝置100,具備照明系10、保持標線片R之標線片載台RST、投影單元PU、裝載晶圓W之晶圓載台WST1、包含WST2之晶圓載台裝置50及此等之控制系等。 The exposure device 100 includes an illumination system 10, a reticle stage RST holding a reticle R, a projection unit PU, a wafer stage WST on which a wafer W is loaded, a wafer stage apparatus 50 including WST2, and the control system thereof Wait.
照明系10,係例如美國專利申請公開第2003/0025890號說明書等所揭示,包含:光源、含光學積分器等之照度均一化光學系、以及具有標線片遮簾等(皆未未圖示)之照明光學系。照明系10藉由照明光(曝光用光)IL以大致均一之照度照明被標線片遮簾(遮蔽系統)規定之標線片R上狹縫狀照明區域IAR。此處,照明光IL,例如係使用ArF準分子雷射光(波長193nm)。 The lighting system 10 is disclosed in, for example, the specification of US Patent Application Publication No. 2003/0025890, and includes: a light source, an illuminance uniformity optical system including an optical integrator, and the like, and a reticle curtain (not shown). ) Of the lighting optics. The illumination system 10 illuminates the slit-shaped illumination area IAR on the reticle R defined by the reticle curtain (shielding system) with illuminating light (exposure light) IL at substantially uniform illuminance. Here, the illumination light IL is, for example, an ArF excimer laser light (wavelength 193 nm).
於標線片載台RST上,以例如真空吸附方式固定有其圖案面(圖1之下面)形成有電路圖案等之標線片R。標線片載台RST能藉由例如包含線性馬達等之標線片載台驅動系11(圖1中未圖示,參照圖6)於XY平面內進行微驅動,並以既定之掃描速度驅動於掃描方向(圖1中與紙面正交之方向之Y軸方向)。 On the reticle stage RST, a reticle R having a circuit pattern or the like formed on its pattern surface (lower side in FIG. 1) is fixed by, for example, a vacuum suction method. The reticle stage RST can be micro-driven in the XY plane by a reticle stage drive system 11 (not shown in FIG. 1, see FIG. 6) including, for example, a linear motor, and driven at a predetermined scanning speed. In the scanning direction (the Y-axis direction in the direction orthogonal to the paper surface in FIG. 1).
標線片載台RST之XY平面(移動面)內之位置資訊(包含θz方向之位置(θz旋轉量)資訊),係以圖1中所示、對移動鏡15(實際上,係設有具有與Y軸方向正交之反射面之Y移動鏡(或復歸反射器)及具有與X軸方向正交之之反射面之X移動鏡)照射測距光束之標線片雷射干涉儀(以下,稱「標線片干涉儀」)16以例如0.25nm程度之解析能力隨時檢測。此外,為測量標線片R之至少3自由度方向之位置資訊,可取代標線片干涉儀16、或與其組合使用例如美國專利申請公開第2007/0288121號說明書等所揭示之編碼器系統。 Position information (including position (θz rotation amount) information in the θz direction) in the XY plane (moving surface) of the reticle stage RST is shown in FIG. 1 for the moving mirror 15 (actually, it is provided with A reticle laser interferometer (or moving reflector with a reflecting surface orthogonal to the Y-axis direction and an X-moving mirror with a reflecting surface orthogonal to the X-axis direction) to irradiate a ranging beam Hereinafter, the "reticle interferometer") 16 is detected at any time with a resolution of, for example, 0.25 nm. In addition, in order to measure the position information in the direction of at least 3 degrees of freedom of the reticle R, the encoder system disclosed in US Patent Application Publication No. 2007/0288121 or the like may be used instead of or in combination with the reticle interferometer 16.
投影單元PU係保持於配置在標線片載台RST之圖1下方(-Z側)、構成未圖示之機體之一部分之主機架(亦稱為計量框架:metrology frame)。投影單元PU具有鏡筒40、以及由保持於該鏡筒40之複數個光學元件構成之 投影光學系PL。投影光學系PL,係使用例如由沿著與Z軸方向平行之光軸AX排列之複數個光學元件(透鏡元件)構成之折射光學系。投影光學系PL係例如兩側遠心、且具有既定投影倍率(例如1/4倍、1/5倍或1/8倍等)。因此,當照明區域IAR被來自照明系10之照明光IL照明時,即藉由通過圖案面與投影光學系PL之第1面(物體面)配置成大致一致之標線片R之照明光IL,透過投影光學系PL將該照明區域IAR內之標線片R之電路圖案縮小像(部分電路圖案之縮小像)形成於配置在投影光學系PL之第2面(像面)側、表面塗有抗蝕劑(感應劑)之晶圓W上之與前述照明區域IAR共軛之區域(曝光區域)IA。接著,藉由同步驅動標線片載台RST與晶圓載台WST1、WST2使標線片R相對照明區域IAR(照明光IL)移動於掃描方向(Y軸方向),並相對曝光區域IA(照明光IL)使晶圓W移動於掃描方向(Y軸方向),據以進行晶圓W上之一個照射區域(區劃區域)之掃描曝光,於該照射區域轉印標線片R之圖案。亦即,本實施形態係藉由照明系10及投影光學系PL於晶圓W上生成標線片R之圖案,並以照明光IL使晶圓W上之感應層(抗蝕層)曝光而於晶圓W上形成該圖案。 The projection unit PU is maintained on a main frame (also referred to as a metrology frame) which is arranged below (-Z side) of the reticle stage RST and constitutes a part of an unillustrated body. The projection unit PU includes a lens barrel 40 and a plurality of optical elements held by the lens barrel 40. Projection optics PL. The projection optical system PL is a refractive optical system composed of a plurality of optical elements (lens elements) arranged along an optical axis AX parallel to the Z-axis direction, for example. The projection optical system PL is, for example, telecentric on both sides and has a predetermined projection magnification (for example, 1/4 times, 1/5 times, or 1/8 times). Therefore, when the illumination area IAR is illuminated by the illumination light IL from the illumination system 10, the illumination light IL of the reticle R that passes through the pattern surface and the first surface (object surface) of the projection optical system PL is arranged to be substantially consistent. , The reduced image of the circuit pattern of the reticle R in the lighting area IAR (a reduced image of a part of the circuit pattern) is formed on the second surface (image surface) side of the projection optical system PL through the projection optical system PL. An area (exposed area) IA on the wafer W having a resist (inductive agent) conjugated to the aforementioned illumination area IAR. Next, by driving the reticle stage RST and the wafer stages WST1 and WST2 synchronously, the reticle R is moved in the scanning direction (Y-axis direction) with respect to the illumination area IAR (illumination light IL), and relative to the exposure area IA (illumination). The light IL) moves the wafer W in the scanning direction (Y-axis direction), thereby performing scanning exposure of an irradiation area (regional area) on the wafer W, and transferring the pattern of the reticle R in the irradiation area. That is, in this embodiment, the pattern of the reticle R is formed on the wafer W by the illumination system 10 and the projection optical system PL, and the induction layer (resist layer) on the wafer W is exposed by the illumination light IL. This pattern is formed on the wafer W.
又,主機架可以是習知所使用之門型、及例如美國專利申請公開第2008/0068568號說明書等所揭示之懸吊支承型之任一種。 In addition, the main frame may be any of a conventional door type and a suspension support type disclosed in, for example, US Patent Application Publication No. 2008/0068568.
於鏡筒40之-Z側端部周圍,和例如鏡筒40之下端面大致同一面高、以和XY平面平行的配置有標尺板21。標尺板21,於本實施形態中,如圖2所示,係由例如L字形之四個部分(零件)211、212、213、214構成,於形成在其中央之例如矩形開口21a內插入鏡筒40之-Z側端部。此處,標尺板21之X軸方向及Y軸方向之寬度分別為a及b、開口21a之X軸方向及Y軸方向之寬度則分別為ai及bi。 A scale plate 21 is arranged around the end of the -Z side of the lens barrel 40 at substantially the same height as the lower end surface of the lens barrel 40 and parallel to the XY plane. The ruler plate 21 in this embodiment, as shown in FIG. 2, is composed of, for example, four parts (parts) 21 1 , 21 2 , 21 3 , and 21 4 in an L-shape, and is formed, for example, in a rectangular opening in the center thereof. The -Z side end of the lens barrel 40 is inserted into 21a. Here, the widths of the X-axis direction and Y-axis direction of the scale plate 21 are a and b, respectively, and the widths of the X-axis direction and Y-axis direction of the opening 21a are ai and bi, respectively.
從標尺板21於+X方向分離之位置,如圖1所示,在與標尺板21大致同一平面上配置有標尺板22。標尺板22,如圖3所示,亦係例如由L字 形之四個部分(零件)221、222、223、224構成,於其中央形成之例如矩形開口22a內插入後述對準系ALG之-Z側端部。標尺板22之X軸方向及Y軸方向之寬度分別為a及b、開口22a之X軸方向及Y軸方向之寬度則分別為ai及bi。又,本實施形態中,雖將於X軸及Y軸方向之標尺板21、22之寬度及開口21a、22a之寬度分別設為相同,但不一定須為相同寬度,亦可於X軸及Y軸方向之至少一方使其寬度不同。 A position separated from the scale plate 21 in the + X direction is, as shown in FIG. 1, a scale plate 22 is disposed on a substantially same plane as the scale plate 21. As shown in FIG. 3, the scale plate 22 is also composed of, for example, four L-shaped parts (parts) 22 1 , 22 2 , 22 3 , and 22 4 , and is inserted into a rectangular opening 22 a formed in the center of the ruler to be described later. It is the end of the -Z side of ALG. The widths of the X-axis direction and Y-axis direction of the scale plate 22 are a and b, respectively, and the widths of the X-axis direction and Y-axis direction of the opening 22a are ai and bi, respectively. In this embodiment, although the widths of the scale plates 21 and 22 and the widths of the openings 21a and 22a in the X-axis and Y-axis directions are set to be the same, respectively, they do not necessarily have to be the same width. At least one of the Y-axis directions has a different width.
本實施形態中,標尺板21、22係被懸吊支承於用以支承投影單元PU及對準系ALG之未圖示之主機架(計量框架:metrology frame)。於標尺板21、22下面(-Z側之面),形成有由以X軸為基準之45度方向(以Y軸為基準之-45度方向)為週期方向之既定間距、例如1μm之光柵、與以X軸為基準之-45度方向(以Y軸為基準之-135度方向)為週期方向之既定間距、例如1μm之光柵構成之反射型二維繞射光柵RG(參照圖2、圖3及圖4)。不過,二維繞射光柵RG及後述編碼器讀頭之構成上,在構成標尺板21、22之部分211~214、221~224各個之外緣近旁包含寬度t之非有效區域。標尺板21、22之二維繞射光柵RG,分別涵蓋至少在曝光動作時及對準(測量)時之晶圓載台WST1、WST2之移動範圍。 In this embodiment, the scale plates 21 and 22 are suspended and supported on a main frame (metrology frame) not shown to support the projection unit PU and the alignment system ALG. Below the scale plates 21 and 22 (surfaces on the -Z side), a predetermined pitch, for example, 1 μm, is formed with a 45-degree direction with the X axis as the reference (-45 degrees with the Y axis as the reference) as the periodic direction. Reflective two-dimensional diffraction grating RG composed of a grating with a predetermined pitch from the -45-degree direction with the X-axis as the reference (-135-degree direction with the Y-axis as the reference), for example, a 1 μm grating (see Figure 2, Figure 3 and Figure 4). However, in the configuration of the two-dimensional diffraction grating RG and the encoder reading head described later, the portions 21 1 to 21 4 and 22 1 to 22 4 constituting the scale plates 21 and 22 include an ineffective region with a width t near each outer edge. . The two-dimensional diffraction gratings RG of the scale plates 21 and 22 respectively cover the movement ranges of the wafer stages WST1 and WST2 at least during the exposure operation and during the alignment (measurement).
晶圓載台裝置50,如圖1所示,具備:以複數(例如三個或四個)防振機構(圖示省略)大致水平支承於地面上之載台基座12、配置在載台基座12上之晶圓載台WST1、WST2、驅動晶圓載台WST1、WST2之晶圓載台驅動系27(圖1中僅顯示一部分、參照圖6)以及測量晶圓載台WST1、WST2之位置之測量系等。測量系具備圖6中所示之編碼器系統70、71及晶圓雷射干涉儀系統(以下,簡稱為晶圓干涉儀系統)18等。又,關於編碼器系統70、71及晶圓干涉儀系統18,留待後述。惟,本實施形態中,並不一定須設置晶圓干涉儀系統18。 As shown in FIG. 1, the wafer stage device 50 includes a stage base 12 that is supported substantially horizontally by a plurality of (for example, three or four) vibration isolation mechanisms (not shown), and is disposed on the stage base. Wafer stage WST1, WST2 on wafer 12, wafer stage drive system 27 (only a part of which is shown in FIG. 1 and FIG. 6) for driving wafer stages WST1, WST2, and a measurement system for measuring the positions of wafer stages WST1 and WST2 Wait. The measurement system includes the encoder systems 70 and 71 shown in FIG. 6, a wafer laser interferometer system (hereinafter, simply referred to as a wafer interferometer system) 18, and the like. The encoder systems 70 and 71 and the wafer interferometer system 18 will be described later. However, in this embodiment, it is not necessary to install the wafer interferometer system 18.
載台基座12,如圖1所示,係由具平板狀外形之構件構成,其上面之 平坦度作成非常高,以作為晶圓載台WST1、WST2移動時之導引面。於載台基座12內部,收容有包含以XY二維方向為行方向、列方向配置成矩陣狀之複數個線圈14a之線圈單元。 The stage base 12, as shown in FIG. 1, is composed of a member having a flat plate shape. The flatness is made very high to serve as a guide surface when the wafer stages WST1 and WST2 move. A coil unit including a plurality of coils 14 a arranged in a matrix with the XY two-dimensional direction as a row direction and a column direction is housed inside the stage base 12.
此外,亦可設置與載台基座12不同之用以懸浮支承此之另一基座構件,令其具有使載台基座12因晶圓載台WST1、WST2之驅動力之反作用力而依據動量守恆定律移動之配衡質量(反作用力抵銷器)之功能。 In addition, another base member different from the stage base 12 for suspending and supporting this can be provided, so that it has a reaction force that causes the stage base 12 to be driven by the driving force of the wafer stages WST1 and WST2, depending on the momentum. The function of balance mass (reaction force canceller) for conservation law movement.
晶圓載台WST1,如圖1所示,具有:載台本體91、以及配置在該載台本體91上方、藉由未圖示之Z傾斜驅動機構以非接觸方式支承於載台本體91之晶圓台WTB1。此場合,晶圓台WTB1係藉由Z傾斜驅動機構以3點調整電磁力等朝上方之力(斥力)與包含自重之朝下方之力(引力)之平衡,以非接觸非常加以支承,且被微驅動於至少Z軸方向、θx方向及θy方向之3自由度方向。於載台本體91之底部設有滑件部91a。滑件部91a具有由在XY平面內XY二維排列之複數個磁石構成之磁石單元、與收容該磁石單元誌筐體、以及設在該筐體底面周圍之複數個空氣軸承。磁石單元與前述線圈單元一起構成例如美國專利第5,196,745號說明書等所揭示之以電磁力(羅倫茲力)驅動之平面馬達30。當然,作為平面馬達30不限於羅倫茲力驅動方式,亦可使用可變磁阻驅動方式之平面馬達。 As shown in FIG. 1, the wafer stage WST1 includes a stage body 91 and a crystal which is disposed above the stage body 91 and is supported by the stage body 91 in a non-contact manner by a Z tilt drive mechanism (not shown). Round table WTB1. In this case, the wafer stage WTB1 adjusts the balance of the upward force (repulsive force) such as electromagnetic force and the downward force (gravity) including its own weight by the Z tilt drive mechanism at three points, and is supported very non-contact, and It is micro-driven in at least three degrees of freedom in the Z-axis direction, the θx direction, and the θy direction. A slider part 91 a is provided on the bottom of the stage body 91. The slider part 91a includes a magnet unit composed of a plurality of magnets arranged two-dimensionally in an XY plane in the XY plane, a casing for housing the magnet unit, and a plurality of air bearings provided around the bottom surface of the casing. The magnet unit and the coil unit constitute a planar motor 30 driven by an electromagnetic force (Lorentz force) as disclosed in, for example, US Pat. No. 5,196,745. Of course, the planar motor 30 is not limited to the Lorentz force driving method, and a planar motor of a variable reluctance driving method can also be used.
晶圓載台WST1係藉由上述複數個空氣軸承、隔著既定間隙(間隔/間隙(gap)/空間距離)、例如數μm程度之間隙懸浮支承於載台基座12上,以平面馬達30驅動於X軸方向、Y軸方向及θz方向。因此,晶圓台WTB1(晶圓W)可相對載台基座12被驅動於6自由度方向(X軸方向、Y軸方向、Z軸方向、θx方向、θy方向及θz方向(以下,簡記為X、Y、Z、θx、θy、θz))。 The wafer stage WST1 is suspended and supported on the stage base 12 by a plurality of air bearings, with a predetermined gap (gap / gap / space distance), for example, a gap of several μm, and is driven by a planar motor 30 In X-axis direction, Y-axis direction, and θz direction. Therefore, the wafer stage WTB1 (wafer W) can be driven in a 6-degree-of-freedom direction (X-axis direction, Y-axis direction, Z-axis direction, θx direction, θy direction, and θz direction (hereinafter, abbreviated) relative to the stage base 12. X, Y, Z, θx, θy, θz)).
本實施形態中,供給至構成線圈單元之各線圈14a之電流大小及方向係以主控制裝置20加以控制。包含平面馬達30與前述Z傾斜驅動機構而構成晶圓載台驅動系27。又,平面馬達30不限於動磁(moving magnet)方式, 亦可以是動圈(moving coil)方式。作為平面馬達30亦可使用、磁浮方式之平面馬達。此場合,可不設置前述空氣軸承。又,亦可使用平面馬達30來進行晶圓載台WST1之6自由度方向驅動。當然,亦可作成使晶圓台WTB1微動於X軸方向、Y軸方向、θz方向中之至少一方向。亦即,可以粗微動載台構成晶圓載台WST1。 In the present embodiment, the magnitude and direction of the current supplied to each coil 14a constituting the coil unit are controlled by the main control device 20. The planar motor 30 and the Z-tilt driving mechanism described above constitute a wafer stage driving system 27. The plane motor 30 is not limited to the moving magnet method. It can also be a moving coil method. The planar motor 30 may be a planar motor of the magnetic levitation method. In this case, the aforementioned air bearing may not be provided. In addition, the planar motor 30 may be used to drive the wafer stage WST1 in the 6-degree-of-freedom direction. Of course, the wafer table WTB1 may be finely moved in at least one of the X-axis direction, the Y-axis direction, and the θz direction. That is, the wafer stage WST1 can be configured as a coarse and fine stage.
於晶圓台WTB1上透過未圖示之晶圓保持具裝載晶圓W、以未圖示之夾頭機構、以例如真空吸附(或靜電吸附)分方加以固定。又,於晶圓台WTB1上之一對角線上,隔著晶圓保持具設有第1基準標記板與第2基準標記板(例如參照圖2)。於此等第1、第2基準標記板上面分別形成有以後述一對標線片對準系13A、13B及對準系ALG加以檢測之複數個基準標記。此處,假設第1、第2基準標記板FM1、FM2上之複數個基準標記彼此之位置關係為已知。 The wafer W is loaded on the wafer table WTB1 through a wafer holder (not shown), and is fixed by a chuck mechanism (not shown), for example, vacuum suction (or electrostatic suction). A first reference mark plate and a second reference mark plate are provided on a diagonal line on the wafer stage WTB1 via the wafer holder (see, for example, FIG. 2). A plurality of reference marks detected by a pair of reticle alignment systems 13A, 13B and alignment system ALG described later are formed on the first and second reference mark plates, respectively. Here, it is assumed that the positional relationship between the plurality of reference marks on the first and second reference mark plates FM1 and FM2 is known.
晶圓載台WST2之構成與晶圓載台WST1相同。 The configuration of the wafer stage WST2 is the same as that of the wafer stage WST1.
編碼器系統70、71係分別用以求出(測量)晶圓載台WST1、WST2在包含緊鄰投影光學系PL下方區域之曝光時移動區域、與包含緊鄰對準系ALG下方區域之測量時移動區域之6自由度方向(X、Y、Z、θx、θy、θz)之位置資訊。此處,詳述編碼器系統70、71之構成等。又,曝光時移動區域(第1移動區域)係在透過投影光學系PL進行晶圓曝光之曝光站(第1區域)內、晶圓載台於曝光動作中移動之區域,該曝光動作不僅是例如晶圓上待轉印圖案之所有照射區域之曝光,亦包含為進行該曝光之準備動作(例如,前述基準標記之檢測)等。測量時移動區域(第2移動區域)係在以對準系ALG進行晶圓對準標記之檢測據以進行其位置資訊之測量之測量站(第2區域)內、晶圓載台於測量動作中移動之區域,該測量動作不僅是例如晶圓之複數個對準標記之檢測,亦包含以對準系ALG進行之基準標記之檢測(以及於Z軸方向之晶圓位置資訊(段差資訊)之測量)等。 The encoder systems 70 and 71 are used to obtain (measure) the wafer stage WST1 and WST2 respectively. The moving area during exposure including the area immediately below the projection optical system PL and the moving area during measurement including the area immediately below the alignment system ALG. Position information in 6 degrees of freedom directions (X, Y, Z, θx, θy, θz). Here, the configuration and the like of the encoder systems 70 and 71 will be described in detail. The exposure movement area (first movement area) is an area where the wafer stage is moved during the exposure operation in the exposure station (first area) where wafer exposure is performed by the projection optical system PL. This exposure operation is not limited to, for example, The exposure of all the irradiated areas of the pattern to be transferred on the wafer also includes preparation operations for performing the exposure (for example, the detection of the aforementioned fiducial mark) and the like. The moving area (second moving area) during measurement is in the measurement station (second area) where the positional information is measured based on the detection of the wafer alignment mark by the alignment system ALG, and the wafer stage is in the measurement operation. For a moving area, the measurement action is not only the detection of a plurality of alignment marks of a wafer, but also the detection of a fiducial mark (and the wafer position information (segment difference information) in the Z-axis direction) performed by the alignment ALG. Measurement) and so on.
於晶圓台WTB1、WTB2,分別如圖2及圖3之俯視圖所示,在上面四角分別配置有編碼器讀頭(以下,適當的簡稱為讀頭)601~604。此處,讀頭601、602間於X軸方向之分離距離與讀頭603、604間於X軸方向之分離距離彼此相等為A。此外,讀頭601、604間於Y軸方向之分離距離與讀頭602、603間於Y軸方向之分離距離彼此相等為B。此等分離距離A、B較標尺板21之開口21a之寬度ai、bi來得大。嚴格來說,考量前述非有效區域之寬度t,為A≧ai+2t、b≧bi+2t。讀頭601~604,如圖4中代表性的舉讀頭601為例所示,係分別被收容在形成於晶圓台WTB1、WTB2之Z軸方向既定深度之孔內部。 On the wafer tables WTB1 and WTB2, as shown in the top views of FIGS. 2 and 3, respectively, encoder read heads (hereinafter, appropriately referred to as read heads) 60 1 to 60 4 are arranged at the upper four corners, respectively. Here, the separation distance between the read heads 60 1 and 60 2 in the X-axis direction and the separation distance between the read heads 60 3 and 60 4 in the X-axis direction are equal to each other as A. In addition, the separation distance between the read heads 60 1 and 60 4 in the Y-axis direction and the separation distance between the read heads 60 2 and 60 3 in the Y-axis direction are equal to each other as B. These separation distances A and B are larger than the widths ai and bi of the opening 21 a of the scale plate 21. Strictly speaking, considering the width t of the inactive area, A ≧ ai + 2t and b ≧ bi + 2t. The read heads 60 1 to 60 4 , as shown in a representative example of the read head 60 1 in FIG. 4, are respectively housed in holes formed at predetermined depths in the Z-axis direction of the wafer tables WTB1 and WTB2.
讀頭601,如圖5所示,係以X軸為基準之135度方向(亦即以X軸為基準之-45度方向)及Z軸方向為測量方向之二維讀頭。同樣的,讀頭602~604亦分別是以X軸為基準之225度方向(亦即以X軸為基準之45度方向)及Z軸方向、以X軸為基準之315度方向(亦即以X軸為基準之-45度方向)及Z軸方向、以X軸為基準之45度方向及Z軸方向為測量方向之二維讀頭。讀頭601~604,由圖2及圖4可知,係分別對對向之標尺板21之部分211~214或標尺板22之部分221~224表面形成之二維繞射光柵RG照射測量光束,並接收來自二維繞射光柵之反射、繞射光束,據以測量於各個測量方向之晶圓台WTB1、WTB2(晶圓載台WST1、WST2)之位置。此處,作為讀頭601~604,可分別使用例如與美國專利第7,561,280號說明書所揭示之位移測量感測器讀頭相同構成之感測器讀頭。 The read head 60 1 , as shown in FIG. 5, is a two-dimensional read head with the X-axis as the reference in the 135-degree direction (that is, the -45-degree direction with the X-axis as the reference) and the Z-axis as the measurement direction. Similarly, the read heads 60 2 to 60 4 are respectively based on the 225-degree direction with the X axis as the reference (that is, the 45-degree direction with the X axis as the reference) and the 315-degree direction with the X axis as the reference ( That is, the two-dimensional read head with the X-axis as the reference -45 degrees) and the Z-axis direction, the X-axis as the reference with 45 degrees and the Z-axis direction as the measurement direction. The reading heads 60 1 to 60 4 , as can be seen from FIG. 2 and FIG. 4, are two-dimensional diffractions formed on the surface of the opposite part 21 1 ~ 21 4 of the scale plate 21 or the part 22 1 ~ 22 4 of the scale plate 22 respectively. The grating RG irradiates the measurement beam, and receives the reflected and diffracted beams from the two-dimensional diffraction grating to measure the positions of the wafer tables WTB1 and WTB2 (wafer stages WST1 and WST2) in each measurement direction. Here, as the read heads 60 1 to 60 4 , for example, sensor read heads having the same configuration as the displacement measurement sensor read head disclosed in the specification of US Pat. No. 7,561,280 can be used.
以上述方式構成之讀頭601~604,由於測量光束在空氣中之光路長極短,因此可幾乎忽視空氣波動之影響。不過,本實施形態中,光源及光檢測器係設在各讀頭之外部、具體而言係設在載台本體91內部(或外部),而僅光學系係設在各讀頭之內部。而光源及光檢測器與光學系係經由未圖示之光纖、光學連接。為提升晶圓台WTB(微動載台)之定位精度,亦可作成 為在載台本體91(粗動載台)與晶圓台WTB(微動載台)之間(以下,簡稱為粗微動載台間)進行雷射光等之空中傳輸,或將讀頭設於載台本體91(粗動載台)而以該讀頭測量載台本體91(粗動載台)之位置、且以另一感測器測量粗微動載台間之相對位移。 The read heads 60 1 to 60 4 constructed in the manner described above, because the optical path of the measurement beam in the air is extremely short, can almost ignore the influence of air fluctuations. However, in this embodiment, the light source and the photodetector are provided outside each read head, specifically inside (or outside) the stage body 91, and only the optical system is provided inside each read head. The light source, light detector, and optical system are optically and optically connected through an optical fiber (not shown). In order to improve the positioning accuracy of the wafer stage WTB (micro-motion stage), it can also be used between the stage body 91 (coarse movement stage) and the wafer stage WTB (micro-motion stage) (hereinafter, referred to as the coarse and micro movement stage) Between stations) for air transmission of laser light, etc., or the reading head is set on the stage body 91 (coarse movement stage) and the position of the stage body 91 (coarse movement stage) is measured by the read head, and another The sensor measures the relative displacement between the coarse and fine moving stages.
在晶圓載台WST1、WST2位於前述曝光時移動區域內時,讀頭601構成為對標尺板21(之部分211)照射測量光束(測量光)、並接收來自形成在標尺板21表面(下面)之以X軸為基準之135度方向、亦即以X軸為基準之-45度方向(以下,僅稱為-45度方向)為週期方向之光柵之繞射光束,以測量晶圓台WTB1、WTB2之-45度方向及Z軸方向位置之二維編碼器701、711(參照圖6)。同樣的,讀頭602~604分別構成對標尺板21(之部分212~214)照射測量光束(測量光)、並接收來自形成在標尺板21表面(下面)之以X軸為基準之225度方向、亦即以X軸為基準之+45度方向(以下,僅稱為45度方向)、315度方向、亦即以X軸為基準之-45度方向、以及以45度方向為週期方向之光柵之繞射光束,以測量晶圓台WTB1、WTB2之225度(45度)方向及Z軸方向位置、315度(-45度)方向及Z軸方向位置、以及45度方向及Z軸方向位置之二維編碼器702~704、712~714(參照圖6)。 When the wafer stages WST1 and WST2 are located within the aforementioned moving range during exposure, the read head 60 1 is configured to irradiate a measuring beam (measurement light) to the scale plate 21 (part 21 1 ) and receive the light beam (measurement light) formed on the surface of the scale plate 21 ( Below) the diffraction beam of the grating with the X-axis as the 135-degree direction, that is, the -45-degree direction with the X-axis as the reference (hereinafter, simply referred to as the -45-degree direction) as the periodic direction, to measure the wafer. The two-dimensional encoders 70 1 and 71 1 in the -45 degree direction and the Z axis direction of the tables WTB1 and WTB2 (see FIG. 6). Similarly, the read heads 60 2 to 60 4 are respectively configured to irradiate the measuring plate 21 (parts 21 2 to 21 4 ) with a measuring beam (measurement light), and receive the X-axis from the surface (lower) of the measuring plate 21 as the The reference 225-degree direction, that is, the + 45-degree direction with reference to the X axis (hereinafter, referred to as the 45-degree direction), the 315-degree direction, that is, the -45-degree direction with the X axis as the reference, and 45 degrees The diffraction beam of the grating in the periodic direction is used to measure the position of the wafer stage WTB1, WTB2 in the 225 ° (45 °) direction and the Z axis direction, the 315 ° (-45 °) direction and the Z axis direction position, and 45 ° Two-dimensional encoders 70 2 to 70 4 and 71 2 to 71 4 in the direction and the Z axis direction (refer to FIG. 6).
又,在晶圓載台WST1、WST2位於前述測量時移動區域內時,讀頭601構成為對標尺板22(之部分221)照射測量光束(測量光)、並接收來自形成在標尺板22表面(下面)以135度方向(-45度方向)為週期方向之光柵之繞射光束,以測量晶圓台WTB1、WTB2之135度方向及Z軸方向位置之二維編碼器701、711(參照圖6)。同樣的,讀頭602~604分別構成為對標尺板22(之部分222~224)照射測量光束(測量光)、並接收來自形成在標尺板22表面(下面)之以225度方向(45度方向)、315度方向(-45度方向)及45度方向為週期方向之光柵之繞射光束,以分別測量晶圓台WTB1、WTB2之225度方向(45度方向)及Z軸方向位置、315度方向(-45度方向)及Z軸方向位 置、及45度方向及Z軸方向位置之二維編碼器702~704、712~714(參照圖6)。 In addition, when the wafer stages WST1 and WST2 are located within the aforementioned moving area during measurement, the read head 60 1 is configured to irradiate a measuring beam (measurement light) to the scale plate 22 (part 22 1 ) and receive the light beam (measurement light) from the scale plate 22. The two-dimensional encoders 70 1 and 71 on the surface (bottom) of the diffraction beam of the grating with the 135-degree direction (-45-degree direction) as the periodic direction to measure the position of the wafer table WTB1, WTB2 in the 135-degree direction and the Z axis direction 1 (see Figure 6). Similarly, the read heads 60 2 to 60 4 are respectively configured to irradiate the measuring plate (parts 222 to 224) with a measuring beam (measurement light), and receive the measuring plate 22 (parts 222 to 224) in a direction of 225 degrees ( 45-degree direction), 315-degree direction (-45-degree direction), and diffracted beams of the gratings in which the 45-degree direction is the periodic direction to measure the 225-degree direction (45-degree direction) and Z-axis direction of the wafer stage WTB1, WTB2, respectively Two-dimensional encoders 70 2 to 70 4 , 71 2 to 71 4 (see FIG. 6) for positions, 315 degrees (-45 degrees) and Z-axis positions, and 45-degree and Z-axis positions.
由上述說明可知,本實施形態中,無論是對標尺板21、22之任一者照射測量光束(測量光),亦即,無論晶圓載台WST1、WST2是在前述曝光時移動區域、測量時移動區域之任一區域內,晶圓載台WST1上之讀頭601~604皆與照射測量光束(測量光)之標尺板一起分別構成二維編碼器701~704,晶圓載台WST2上之讀頭601~604皆與照射測量光束(測量光)之標尺板一起分別構成二維編碼器711~714。 As can be seen from the above description, in this embodiment, regardless of whether the measurement plates (measurement light) are irradiated to any of the scale plates 21 and 22, that is, regardless of whether the wafer stages WST1 and WST2 are moved during the exposure, or during measurement, In any of the moving areas, the read heads 60 1 to 60 4 on the wafer stage WST1 together with the scale plate that irradiates the measuring beam (measurement light) constitute two-dimensional encoders 70 1 to 70 4 respectively , and the wafer stage WST2 The above-mentioned read heads 60 1 to 60 4 each form a two-dimensional encoder 71 1 to 71 4 together with a scale plate that irradiates a measuring beam (measuring light).
二維編碼器(以下,適當的簡稱為編碼器)701~704、711~714之各編碼器之測量值係供應至主控制裝置20(參照圖6)。主控制裝置20根據與形成有二維繞射光柵RG之標尺板21(構成之部分211~214)下面對向之至少三個編碼器(亦即,輸出有效測量值之至少三個編碼器)之測量值,求出晶圓台WTB1、WTB2在包含緊鄰投影光學系PL下方區域之曝光時移動區域內之位置資訊。同樣的,主控制裝置20根據與形成有二維繞射光柵RG之標尺板22(構成之部分221~224)下面對向之至少三個編碼器(亦即,輸出有效測量值之至少三個編碼器)之測量值,求出晶圓台WTB1、WTB2在包含緊鄰對準系ALG下方區域之測量時移動區域內之位置資訊。 The measured values of the two-dimensional encoders (hereinafter, appropriately referred to as encoders) 70 1 to 70 4 and 71 1 to 71 4 are supplied to the main control device 20 (see FIG. 6). The main control device 20 is based on at least three encoders (i.e., at least three output valid measurement values) facing the scale plate 21 (constituting parts 21 1 to 21 4 ) formed with a two-dimensional diffraction grating RG. Encoder) to obtain the position information of the wafer table WTB1, WTB2 in the moving area during exposure including the area immediately below the projection optical system PL. Similarly, the main control device 20 is based on at least three encoders (i.e., outputs valid measurement values) facing the scale plate 22 (constituting parts 22 1 to 22 4 ) on which the two-dimensional diffraction grating RG is formed. (At least three encoders) to obtain the position information of the wafer table WTB1, WTB2 in the moving area when the measurement includes the area immediately below the alignment system ALG.
又,本實施形態之曝光裝置100中,晶圓載台WST1、WST2(晶圓台WTB1、WTB2)之位置可藉由晶圓干涉儀系統18(參照圖6)而與編碼器系統70、71分開獨立的加以測量。晶圓干涉儀系統18之測量結果,係係輔助性的用於修正(校正)編碼器系統70、71之測量值之長期變動(例如標尺之經時變形等造成)之情形時、或編碼器系統70、71之輸出異常時之備用等。此處,省略晶圓干涉儀系統18之詳細說明。 In the exposure apparatus 100 of this embodiment, the positions of the wafer stages WST1 and WST2 (wafer stages WTB1 and WTB2) can be separated from the encoder systems 70 and 71 by the wafer interferometer system 18 (see FIG. 6). Measured independently. The measurement result of the wafer interferometer system 18 is an auxiliary condition for correcting (correcting) long-term changes in the measurement values of the encoder systems 70 and 71 (such as caused by time-dependent deformation of the scale), or the encoder Standby when the output of system 70, 71 is abnormal. Here, detailed description of the wafer interferometer system 18 is omitted.
對準系ALG,如圖1所示,係在投影光學系PL之+X側相隔既定間隔配置之離軸方式之對準系。本實施形態中,作為對準系ALG,例如係使 用以鹵素燈等之寬頻光照明標記,並藉由對此標記影像進行影像處理據以測量標記位置之影像處理方式對準感測器之一種的FIA(Field Image Alignment)系。來自對準系ALG之攝影訊號透過未圖示之對準訊號處理系供應至主控制裝置20(參照圖6)。 The alignment system ALG, as shown in FIG. 1, is an off-axis alignment system arranged at a predetermined interval on the + X side of the projection optical system PL. In this embodiment, as the alignment system ALG, for example, A type of FIA (Field Image Alignment) system that illuminates a mark with a wide band light such as a halogen lamp and performs image processing on the mark image to measure the mark position. The photographic signal from the alignment system ALG is supplied to the main control device 20 (see FIG. 6) through an alignment signal processing system (not shown).
又,對準系ALG不限於FIA系,當然亦可單獨或適當組合使用例如對標記照射相干的(coherent)檢測光,並檢測從該標記產生之散射光或繞射光、或使從標記產生之二個繞射光(例如同次數之繞射光、或繞射於同方向之繞射光)干涉後加以檢測之對準感測器。作為對準系ALG,亦可使用例如美國專利申請公開第2008/0088843號說明書等所揭示之具有複數個檢測區域之對準系。 The alignment system ALG is not limited to the FIA system. Of course, it is also possible to use a coherent detection light on the mark alone or in appropriate combination, and to detect scattered light or diffracted light generated from the mark, or to generate light from the mark. An alignment sensor that detects two diffracted lights (such as diffracted lights of the same order or diffracted lights in the same direction) and then detects them. As the alignment system ALG, an alignment system having a plurality of detection areas disclosed in, for example, US Patent Application Publication No. 2008/0088843 can also be used.
此外,於本實施形態之曝光裝置100,設有與對準系ALG一起配置於測量站、與例如美國專利第5,448,332號說明書等所揭示者相同構成之斜入射方式之多點焦點位置檢測系(以下,簡稱為多點AF系)AF(圖1中未圖示,參照圖6)。以多點AF系AF進行之測量動作,其至少一部分係與以對準系ALG進行之標記檢測動作平行進行,且使用前述編碼器系統於該測量動作中測量晶圓台之位置資訊。多點AF系AF之檢測訊號經由AF訊號處理系(未圖示)供應至主控制裝置20(參照圖6)。主控制裝置20根據多點AF系AF之檢測訊號與前述編碼器系統之測量資訊,檢測晶圓W表面之Z軸方向之位置資訊(段差資訊/凹凸資訊),曝光動作係根據該事前檢測資訊與前述編碼器系統之測量資訊(Z軸、θx及θy方向之位置資訊)實施掃描曝光中晶圓W之所謂的聚焦、調平控制。又,亦可在曝光站內於投影單元PU近旁設置多點AF系,於曝光動作時一邊測量晶圓表面之位置資訊(凹凸資訊)一邊驅動晶圓台,來實施晶圓W之聚焦、調平控制。 In addition, the exposure apparatus 100 of this embodiment is provided with a multi-point focus position detection system of an oblique incidence method arranged at a measuring station together with the alignment system ALG and having the same structure as disclosed in, for example, US Pat. No. 5,448,332. Hereinafter, referred to as a multi-point AF system) AF (not shown in FIG. 1, refer to FIG. 6). At least a part of the measurement operation performed with the multi-point AF system AF is performed in parallel with the mark detection operation performed with the alignment system ALG, and the position information of the wafer stage is measured in the measurement operation using the aforementioned encoder system. The detection signal of the multi-point AF system AF is supplied to the main control device 20 (refer to FIG. 6) via an AF signal processing system (not shown). The main control device 20 detects the position information (step difference information / concave and convexity information) of the Z axis direction of the wafer W surface based on the detection signal of the multi-point AF system AF and the measurement information of the aforementioned encoder system, and the exposure operation is based on the prior detection information The so-called focus and leveling control of the wafer W in the scanning exposure is implemented with the measurement information (position information in the Z-axis, θx, and θy directions) of the aforementioned encoder system. In addition, a multi-point AF system can be installed near the projection unit PU in the exposure station. During the exposure operation, the wafer table is driven while measuring the position information (concave and convexity information) of the wafer surface to perform the focusing and leveling of the wafer W. control.
曝光裝置100中,進一步的於標線片R之上方設有例如美國專利第5,646,413號說明書等所揭示之使用曝光波長之光之TTR(Through The Reticle)方式之一對標線片對準系13A、13B(圖1中未圖示,參照圖6)。標線片對準系13A、13B之檢測訊號經由未圖示之對準訊號處理系供應至主控制裝置20。又,亦可取代標線片對準系而使用設在晶圓載台WST上之未圖示之空間像測量器進行標線片對準。 In the exposure apparatus 100, a TTR (Through The) using light of an exposure wavelength as disclosed in, for example, US Pat. No. 5,646,413 is further provided above the reticle R. One of the Reticle) methods is a reticle alignment system 13A, 13B (not shown in FIG. 1, see FIG. 6). The detection signals of the reticle alignment systems 13A and 13B are supplied to the main control device 20 through an alignment signal processing system (not shown). In addition, instead of the reticle alignment system, an unillustrated aerial image measuring device provided on the wafer stage WST may be used to perform reticle alignment.
圖6係曝光裝置100之與載台控制關聯之控制系之部分省略的方塊圖。此控制系係以主控制裝置20為中心而構成。主控制裝置20包含由CPU(中央運算處理裝置)、ROM(唯讀記憶體)、RAM(隨機存取記憶體)等構成之所謂的微電腦(或工作站),統籌控制裝置全體。 FIG. 6 is a block diagram of a part of the control system related to stage control of the exposure apparatus 100 which is omitted. This control system is structured around the main control device 20. The main control device 20 includes a so-called microcomputer (or workstation) composed of a CPU (Central Processing Unit), ROM (Read Only Memory), RAM (Random Access Memory), etc., and coordinates the entire control device.
以上述方式構成之曝光裝置100,於元件之製造時,藉由主控制裝置20使裝載了晶圓之晶圓載台WST1、WST2之一方在測量站(測量時移動區域)內移動,以實施使用對準系ALG及多點AF系之晶圓測量動作。亦即,針對在測量時移動區域內晶圓載台WST1、WST2之一方所保持之晶圓W,進行使用對準系ALG之標記檢測、所謂的晶圓對準(例如美國專利第4,780,617號說明書等所揭示之全晶圓加強型對準(EGA)等)、與使用多點AF系之晶圓面資訊(段差/凹凸資訊)之測量。此時,以編碼器系統70(編碼器701~704)或編碼器系統71(編碼器711~714)求出(測量)晶圓載台WST1、WST2之6自由度方向(X、Y、Z、θx、θy、θz)之位置資訊。 The exposure device 100 configured as described above is used by the main control device 20 to move one of the wafer stages WST1 and WST2 on which the wafer is loaded in the measurement station (moving area during measurement) to manufacture the device. Alignment system ALG and multi-point AF system wafer measurement operation. That is, the wafer W held by one of the wafer stages WST1 and WST2 in the moving area during measurement is subjected to mark detection using an alignment system ALG, so-called wafer alignment (for example, US Patent No. 4,780,617, etc.) The disclosed full wafer enhanced alignment (EGA), etc., and the measurement of wafer surface information (segmentation / bump information) using multi-point AF system. At this time, the encoder system 70 (encoders 70 1 to 70 4 ) or encoder system 71 (encoders 71 1 to 71 4 ) is used to determine (measure) the 6-degree-of-freedom directions (X, Y, Z, θx, θy, θz).
晶圓對準等之測量動作後,一方之晶圓載台(WST1或WST2)移動至曝光時移動區域,藉由主控制裝置20,使用標線片對準系13A、13B、晶圓台(WTB1或WTB2)上之基準標記板(未圖示)等,以和一般掃描步進機相同之程序(例如美國專利第5,646,413號說明書等所揭示之程序)進行標線片對準等。 After measurement operations such as wafer alignment, one wafer stage (WST1 or WST2) is moved to the movement area during exposure. The main control device 20 uses a reticle alignment system 13A, 13B, and a wafer stage (WTB1 Or WTB2) on a reference mark plate (not shown), etc., for reticle alignment, etc., using the same procedure as a general scanning stepper (for example, the procedure disclosed in US Pat. No. 5,646,413).
接著,由主控制裝置20根據晶圓對準等之測量結果進行步進掃描方式之曝光動作,將標線片R之圖案分別轉印至晶圓W上之複數個照射區域。步進掃描方式之曝光動作,係藉由交互的反覆實施進行標線片載台RST與 晶圓載台WST1或WST2之同步移動之掃描曝光動作、與將晶圓載台WST1或WST2移動至為進行照射區域曝光之加速開始位置之照射間移動(步進)動作,據以進行。於曝光動作時,以編碼器系統70(編碼器701~704)或編碼器系統71(編碼器711~714)求出(測量)一方之晶圓載台(WST1或WST2)之6自由度方向(X、Y、Z、θx、θy、θz)之位置資訊。 Next, the main control device 20 performs an exposure operation in a step-and-scan manner according to the measurement results of wafer alignment and the like, and transfers the patterns of the reticle R to a plurality of irradiation areas on the wafer W, respectively. The exposure operation in the step-and-scan method is a scanning exposure operation in which the reticle stage RST and the wafer stage WST1 or WST2 are moved synchronously and repeatedly, and the wafer stage WST1 or WST2 is moved to perform irradiation. The movement (stepping) operation between the acceleration start positions of the area exposures is performed accordingly. During the exposure operation, use encoder system 70 (encoders 70 1 to 70 4 ) or encoder system 71 (encoders 71 1 to 71 4 ) to determine (measure) one of the wafer stages (WST1 or WST2). Position information in degrees of freedom (X, Y, Z, θx, θy, θz).
又,本實施形態之曝光裝置100具備二個晶圓載台WST1、WST2。因此,係進行下述平行處理動作,亦即與對一方之晶圓載台、例如裝載於晶圓載台WST1上之晶圓進行步進掃描方式之曝光,並與此平行的,進行對另一方之晶圓載台WST2上裝載之晶圓進行晶圓對準等。 The exposure apparatus 100 according to this embodiment includes two wafer stages WST1 and WST2. Therefore, the following parallel processing operations are performed, that is, stepwise scanning exposure is performed on one wafer stage, for example, the wafer loaded on the wafer stage WST1, and parallel to this, the other side is exposed. The wafer loaded on the wafer stage WST2 is used for wafer alignment and the like.
本實施形態之曝光裝置100,如前所述,主控制裝置20在曝光時移動區域內及測量時移動區域內之任一者時,皆使用編碼器系統70(參照圖6)求出(測量)晶圓載台WST1之6自由度方向(X、Y、Z、θx、θy、θz)之位置資訊。又,主控制裝置20,在曝光時移動區域內及測量時移動區域內之任一者時,皆使用編碼器系統71(參照圖6)求出(測量)晶圓載台WST2之6自由度方向(X、Y、Z、θx、θy、θz)之位置資訊。 As described above, in the exposure device 100 of this embodiment, the main control device 20 uses the encoder system 70 (refer to FIG. 6) to determine (measurement) any of the moving area during exposure and the moving area during measurement. ) Position information of the 6-degree-of-freedom directions (X, Y, Z, θx, θy, θz) of the wafer stage WST1. In addition, the main control device 20 obtains (measures) the 6-degree-of-freedom direction of the wafer stage WST2 using the encoder system 71 (see FIG. 6) in either the exposure area or the measurement area during measurement. (X, Y, Z, θx, θy, θz).
接著,進一步說明使用編碼器系統70、71之XY平面內之3自由度方向(X軸方向、Y軸方向及θz方向(亦簡記為X、Y、θz))之位置測量原理等。此處,編碼器讀頭601~604或編碼器701~704之測量結果或測量值,係指編碼器讀頭601~604或編碼器701~704之非Z軸方向之測量方向之測量結果。 Next, the principle of position measurement using the three-degree-of-freedom directions (X-axis direction, Y-axis direction, and θz direction (also abbreviated to X, Y, θz)) in the XY plane of the encoder systems 70 and 71 will be further explained. Here, the encoder 1 to the read head 60 measured by the encoder 604 or 701 ~ 704 or the result of measurements, the read head 60 refers to the encoder 1 to the encoder 604 or non Z-axis of 701 ~ 704 Measurement of the direction.
本實施形態,藉由採用前述編碼器讀頭601~604及標尺板21之構成及配置,在曝光時移動區域內,編碼器讀頭601~604中之至少三個、可恆與標尺板21(之對應部分211~214)對向。 In this embodiment, by adopting the structure and arrangement of the aforementioned encoder reading heads 60 1 to 60 4 and the scale plate 21, at least three of the encoder reading heads 60 1 to 60 4 can be constant in the moving area during exposure. It is opposite to the ruler plate 21 (the corresponding parts 21 1 to 21 4 ).
圖7(A)中顯示了晶圓載台WST1上之編碼器讀頭601~604及標尺板21之各部分211~214之配置與編碼器系統70之測量區域A0~A4之關係。又, 由於晶圓載台WST2與晶圓載台WST1同樣構成,因此,此處僅說明晶圓載台WST1。 Figure 7 shows an encoder on the wafer stage WST1 heads 601 ~ 604 and the respective portions 21 of measurement 21 1 to 21 4 of the configuration of encoder system 70 of the region A scale plate 0 ~ A 4 (A) in Relationship. Since the wafer stage WST2 has the same configuration as the wafer stage WST1, only the wafer stage WST1 will be described here.
當晶圓載台WST1之中心(與晶圓之中心一致)位於曝光時移動區域內、且相對曝光中心(曝光區域IA之中心)P位置+X側且+Y側之區域(以曝光中心P為原點之第1象限內區域(惟,不含區域A0))之第1區域A1內時,晶圓載台WST1上之讀頭604、601、602分別對向於標尺板21之部分214、211、212。於第1區域A1內,從讀頭604、601、602(編碼器704、701、702)將有效測量值送至主控制裝置20。以下說明中之晶圓載台WST1、WST2之位置,係指該晶圓載台之中心(與晶圓之中心一致)位置。亦即,將晶圓載台WST1、WST2之中心之位置記載為晶圓載台WST1、WST2之位置。 When the center of wafer stage WST1 (consistent with the center of the wafer) is located in the moving area during exposure, and is located on the + X side and + Y side relative to the exposure center (center of exposure area IA) P (the exposure center P is the quadrant region of origin (but, excluding the region A 0) within the A 1) of the first region, the wafer stage WST1 on the read heads 604, 601, 602 respectively of the scale plate 21 to Part 21 4 , 21 1 , 21 2 . In the first area A 1 , the effective measurement values are sent from the read heads 60 4 , 60 1 , and 60 2 (encoders 70 4 , 70 1 , and 70 2 ) to the main control device 20. The positions of the wafer stages WST1 and WST2 in the following description refer to the position of the center of the wafer stage (which is the same as the center of the wafer). That is, the positions of the centers of the wafer stages WST1 and WST2 are described as the positions of the wafer stages WST1 and WST2.
同樣的,當晶圓載台WST1於曝光時移動區域內、且相對曝光中心P位置-X側且+Y側區域(以曝光中心P為原點之第2象限內區域(惟,不含區域A0))之第2區域A2內時,讀頭601、602、603分別對向於標尺板21之部分211、212、213。當晶圓載台WST1於曝光時移動區域內、且相對曝光中心P位置-X側且-Y側區域(以曝光中心P為原點之第3象限內區域(惟,不含區域A0))之第3區域A3內時,讀頭602、603、604分別對向於標尺板21之部分212、213、214。當晶圓載台WST1於曝光時移動區域內、且相對曝光中心P位置+X側且-Y側區域(以曝光中心P為原點之第4象限內區域(惟,不含區域A0))之第4區域A4內時,讀頭603、604、601分別對向於標尺板21之部分213、214、211。 Similarly, when the wafer stage WST1 is moved during exposure, it is located in the -X side and + Y side area relative to the exposure center P (the area in the second quadrant with the exposure center P as the origin (but excluding area A) 0 )) in the second area A 2 , the read heads 60 1 , 60 2 , and 60 3 face the portions 21 1 , 21 2 , and 21 3 of the scale plate 21, respectively. When the wafer stage WST1 is moved during exposure, it is located in the -X side and -Y side relative to the exposure center P position (the area in the third quadrant with the exposure center P as the origin (but excluding the area A 0 )) In the third area A 3 , the read heads 60 2 , 60 3 , and 60 4 face the portions 21 2 , 21 3 , and 21 4 of the scale plate 21, respectively. When the wafer stage WST1 is moved during exposure, it is in the + X side and -Y side area relative to the exposure center P position (the area in the 4th quadrant with the exposure center P as the origin (but excluding area A 0 )) In the fourth area A 4 , the read heads 60 3 , 60 4 , and 60 1 face the portions 21 3 , 21 4 , and 21 1 of the scale plate 21, respectively.
本實施形態中,關於前述編碼器讀頭601~604及標尺板21之構成及配置之條件(A≧ai+2t、B≧bi+2t)下,如圖7(A)所示,當晶圓載台WST1位於以曝光中心P為中心之十字形區域A0(包含以通過曝光中心P之Y軸方向為長邊方向之寬度A-ai-2t之區域、與以X軸方向為長邊方向之寬度B-bi-2t之區域的區域(以下,稱第0區域))內之情形時,晶圓載台WST1 上之所有讀頭601~604對向於標尺板21(對應之部分211~214)。因此,在第0區域A0內,從所有讀頭601~604(編碼器701~704)將有效測量值送至主控制裝置20。又,本實施形態中除上述條件(A≧ai+2t、B≧bi+2t)外,亦可考慮形成圖案之晶圓上照射區域之尺寸(W、L),而再加上條件A≧ai+W+2t、B≧bi+L+2t。此處、W、L分別為照射區域之X軸方向、Y軸方向之寬度。W、L分別與掃描曝光區間之距離、往X軸方向之步進距離相等。 In this embodiment, under the conditions (A ≧ a i + 2t, B ≧ b i + 2t) regarding the configuration and arrangement of the encoder read heads 60 1 to 60 4 and the scale plate 21, as shown in FIG. 7 (A) When the wafer stage WST1 is located in the cross-shaped area A 0 centered on the exposure center P (including the area of the width A-ai-2t with the Y-axis direction passing through the exposure center P as the long side direction, and the X-axis direction) In the case of the area (hereinafter, referred to as the 0th area) with a width of B-bi-2t in the longitudinal direction, all the read heads 60 1 to 60 4 on the wafer stage WST1 are opposed to the scale plate 21 ( Corresponding part 21 1 ~ 21 4 ). Therefore, in the 0th area A 0 , the effective measurement values are sent from all the read heads 60 1 to 60 4 (encoders 70 1 to 70 4 ) to the main control device 20. In addition, in this embodiment, in addition to the above conditions (A ≧ ai + 2t, B ≧ bi + 2t), the size (W, L) of the irradiation area on the patterned wafer can also be considered, and the condition A ≧ ai + W + 2t, B ≧ bi + L + 2t. Here, W and L are the widths in the X-axis direction and the Y-axis direction of the irradiation area, respectively. W and L are respectively equal to the distance of the scanning exposure interval and the step distance to the X-axis direction.
主控制裝置20根據讀頭601~604(編碼器701~704)之測量結果,算出晶圓載台WST1在XY平面內之位置(X、Y、θz)。此處,編碼器701~704之測量值(分別記載為C1~C4)係如次式(1)~(4)所示,依存於晶圓載台WST1之位置(X、Y、θz)。 The main control device 20 calculates the position (X, Y, θz) of the wafer stage WST1 in the XY plane based on the measurement results of the read heads 60 1 to 60 4 (encoders 70 1 to 70 4 ). Here, the measured values of the encoders 70 1 to 70 4 (respectively described as C 1 to C 4 ) are as shown in the following equations (1) to (4), and depend on the position of the wafer stage WST1 (X, Y, θz).
其中,如圖5所示,p係從晶圓台WTB1(WTB2)中心於讀頭之X軸及Y軸方向之距離。 Among them, as shown in FIG. 5, p is the distance from the center of the wafer table WTB1 (WTB2) to the X-axis and Y-axis directions of the read head.
主控制裝置20,依據晶圓載台WST1所在之區域A0~A4特定出與標尺板21對向之三個讀頭(編碼器),並從上式(1)~(4)中選擇該等測量值依據之式來組合連立方程式,使用三個讀頭(編碼器)之測量值解連立方程式,據以算出晶圓載台WST1於XY平面內之位置(X、Y、θz)。例如,晶圓載台WST1位於第1區域A1內之情形時,主控制裝置20從讀頭601、602、604(編碼器 701、702、704)之測量值依據之式(1)、(2)及(4)組合連立方程式,將各讀頭之測量值代入式(1)、(2)及(4)各式左邊以解連立方程式。將算出之位置(X、Y、θz)記載為X1、Y1、θz1。同樣的,當晶圓載台WST1位於第k區域Ak內時,主控制裝置20從讀頭60k-1、60k、60k+1(編碼器70k-1、70k、70k+1)之依據之測量值(k-1),(k)及(k+1)組合連立方程式,將各讀頭之測量值代入該等式之左邊以解連立方程式。據此,算出位置(Xk、Yk、θzk)。此處,於k-1、k及k+1係代入1~4週期性置換之數。 The main control device 20 specifies three reading heads (encoders) facing the scale plate 21 according to the areas A 0 to A 4 where the wafer stage WST1 is located, and selects the reading heads from the above formulas (1) to (4). Combine the simultaneous equations according to the equations based on the measured values, and use the measured values of the three read heads (encoders) to solve the simultaneous equations to calculate the position (X, Y, θz) of the wafer stage WST1 in the XY plane. For example, when the wafer stage WST1 is located in the first area A 1 , the measured values of the master control device 20 from the read heads 60 1 , 60 2 , and 60 4 (encoders 70 1 , 70 2 , and 70 4 ) are based on the formula: (1), (2), and (4) combine the simultaneous equations, and substitute the measured values of each read head into the left side of each of the equations (1), (2), and (4) to solve the simultaneous equations. The calculated positions (X, Y, θz) are described as X 1 , Y 1 , θz 1 . Similarly, when the wafer stage WST1 is located in the k-th region Ak , the master control device 20 reads 60 k-1 , 60 k , 60 k + 1 (encoders 70 k-1 , 70 k , 70 k +) from the read head . 1 ) Based on the measured values (k-1), (k) and (k + 1) combined simultaneous equations, substitute the measured values of each read head to the left of the equations to solve the simultaneous equations. From this, positions (X k , Y k , θz k ) are calculated. Here, k-1, k, and k + 1 are substituted into the numbers of 1-4 periodic replacements.
又,當晶圓載台WST1位置第0區域A0內之情形時,主控制裝置20從讀頭601~604(編碼器701~704)中選擇任意三個即可。例如,在晶圓載台WST1從第1區域移動至第0區域後,選擇與第1區域對應之讀頭601、602、604(編碼器701、702、704)即可。 When the wafer stage WST1 is located in the 0th area A 0 , the main control device 20 may select any three of the read heads 60 1 to 60 4 (encoders 70 1 to 70 4 ). For example, after the wafer stage WST1 is moved from the first area to the 0th area, the read heads 60 1 , 60 2 , and 60 4 (encoders 70 1 , 70 2 , and 70 4 ) corresponding to the first area may be selected.
主控制裝置20根據上述算出結果(X、Y、θz),於曝光時移動區域內驅動晶圓載台WST1(進行位置控制)。 Based on the calculation results (X, Y, θz) described above, the main control device 20 drives the wafer stage WST1 in the moving area during exposure (performs position control).
當晶圓載台WST1位於測量時移動區域內之情形時,主控制裝置20使用編碼器系統70測量3自由度方向(X、Y、θz)之位置資訊。此處,關於測量原理等,除曝光中心P更換為對準系ALG之檢測中心、標尺板21(之部分211~214)更換為標尺板22(之部分221~224)外,與晶圓載台WST1位於之前之曝光時移動區域內之情形相合。 When the wafer stage WST1 is located in the moving area during measurement, the main control device 20 uses the encoder system 70 to measure the position information in the 3 degrees of freedom direction (X, Y, θz). Here, regarding the measurement principle, etc., except that the exposure center P is replaced with the detection center of the alignment system ALG, and the ruler plate 21 (part 21 1 to 21 4 ) is replaced with the ruler plate 22 (part 22 1 to 22 4 ). This is consistent with the situation where the wafer stage WST1 is located in the moving area during the previous exposure.
進一步的,主控制裝置20依據晶圓載台WST1、WST2之位置,將與標尺板21、22對向之讀頭601~604中之三個,切換為至少一個不同之三個加以使用。此處,於切換編碼器讀頭時,係進行例如美國專利申請公開第2008/0094592號說明書等所揭示之確保晶圓載台位置測量結果之連續性的接續處理。 Further, according to the positions of the wafer stages WST1 and WST2, the main control device 20 switches three of the read heads 60 1 to 60 4 facing the scale plates 21 and 22 to at least one different three for use. Here, when the encoder read head is switched, for example, a splicing process for ensuring the continuity of the measurement result of the wafer stage position disclosed in, for example, US Patent Application Publication No. 2008/0094592 is performed.
如前所述,於本實施形態之曝光裝置100中之標尺板21、22係分別由四個部分211~214、221~224構成。此處,當四個部分、嚴格來說當形成在 四個部分下面之二維繞射光柵RG彼此偏差時,即會產生編碼器系統70、71之測量誤差。 As described above, the scale plates 21 and 22 in the exposure apparatus 100 of this embodiment are respectively composed of four sections 21 1 to 21 4 and 22 1 to 22 4 . Here, when the four parts, strictly speaking, the two-dimensional diffraction gratings RG formed under the four parts deviate from each other, a measurement error of the encoder systems 70, 71 will occur.
圖7(B)及圖7(C)中,以示意方式顯示了與在第k區域Ak(k=1~4)內從讀頭60k-1、60k、60k+1(編碼器70k-1、70k、70k+1或編碼器71k-1、71k、71k+1)之有效測量值算出之晶圓載台WST1或WST2之位置(Xk、Yk、θzk)對應之第k基準座標系Ck(k=1~4)。四個基準座標系C1~C4對應區域A1~A4(參照圖7(A))之配置,在原點O近旁彼此重複,在以原點O為中心之十字形區域C0與相鄰接之基準座標系重複。 In Fig. 7 (B) and Fig. 7 (C), it is shown in a schematic way that the read heads 60 k-1 , 60 k , and 60 k + 1 (coded in the k-th region A k (k = 1 ~ 4)) Position ( Xk , Yk , WST1 or WST2) of wafer stage WST1 or WST2 calculated by the effective measurement of encoder 70 k-1 , 70 k , 70 k + 1 or encoder 71 k-1 , 71 k , 71 k + 1 ). θz k ) corresponds to the k-th reference coordinate system C k (k = 1 ~ 4). The arrangement of the four reference coordinate systems C 1 to C 4 corresponding to the areas A 1 to A 4 (see FIG. 7 (A)) is repeated near the origin O, and in the cross-shaped area C 0 centered at the origin O and the phase Adjacent datum coordinates are repeated.
當標尺板21之構成如設計值時,亦即,形成在四個部分211~214之二維繞射光柵RG彼此間未偏差時,如圖7(B)所示,四個基準座標系C1~C4各自之原點O1~O4彼此一致(圖中,以符號O表示)、旋轉θz1~θz4及定標(scaling)Γx1~Γx4、Γy1~Γy4亦彼此一致。因此,可將四個基準座標系統合為一個座標系CE。亦即,可將曝光時在移動區域A1~A4內之晶圓載台WST1、WST2之位置,以在統合座標系CE之位置座標X、Y、θz加以表示。 When the configuration of the scale plate 21 is as designed, that is, when the two-dimensional diffraction gratings RG formed in the four sections 21 1 to 21 4 are not deviated from each other, as shown in FIG. 7 (B), the four reference coordinates The respective origins O 1 to O 4 of C 1 to C 4 are consistent with each other (in the figure, represented by the symbol O), rotation θz 1 to θz 4 and scaling Γx 1 to Γx 4 , Γy 1 to Γy 4 Also agree with each other. Therefore, the four reference coordinate systems can be combined into one coordinate system C E. That is, the positions of the wafer stages WST1 and WST2 in the moving areas A 1 to A 4 at the time of exposure can be represented by the coordinates X, Y, and θz in the position of the integrated coordinate system C E.
然而,形成在四個部分211~214之二維繞射光柵RG彼此間有偏差時,如圖7(C)所示,四個基準座標系C1~C4各自之原點O1~O4、旋轉θz1~θz4及定標Γx1~Γx4、Γy1~Γy4產生偏差,伴隨於此而產生測量誤差。因此,圖7(B)所示之例,無法將四個基準座標系統合為一個座標系CE。 However, when the two-dimensional diffraction gratings RG formed in the four portions 21 1 to 21 4 are deviated from each other, as shown in FIG. 7 (C), the respective origins O 1 of the four reference coordinate systems C 1 to C 4 ~ O 4 , rotations θz 1 to θz 4, and calibrations Γx 1 to Γx 4 , Γy 1 to Γy 4 are subject to deviations, and measurement errors are accompanied by the deviations. Therefore, in the example shown in FIG. 7 (B), the four reference coordinate systems cannot be combined into one coordinate system C E.
同樣的,當構成標尺板22之四個部分221~224、嚴格來說當形成在四個部分221~224下面之二維繞射光柵RG彼此偏差時,即會產生編碼器系統70或71之測量誤差。 Similarly, when the four parts 22 1 to 22 4 constituting the scale plate 22 are strictly speaking, when the two-dimensional diffraction gratings RG formed under the four parts 22 1 to 22 4 deviate from each other, an encoder system is generated. Measurement error of 70 or 71.
因此,本實施形態,採用了校正因構成標尺板21、22之部分211~214、221~224彼此間偏差導致之四個基準座標系C1~C4彼此間偏差之校正方法。接著,以標尺板21為例,詳細說明校正方法。 Therefore, in this embodiment, a correction method is used to correct the deviations of the four reference coordinate systems C 1 to C 4 caused by the deviations between the parts 21 1 to 21 4 and 22 1 to 22 4 constituting the scale plates 21 and 22. . Next, the calibration method will be described in detail using the scale plate 21 as an example.
首先,主控制裝置20,如圖8(A)所示,將晶圓載台WST1(WST2)定位 在區域A0內。圖8(A)中,晶圓載台WST1係被定位在區域A0之中央(緊臨投影光學系PL下方)。於區域A0內,晶圓載台WST1上所搭載之讀頭601~604全部對向於標尺板21(之對應部分211~214),將有效測量值送至主控制裝置20。主控制裝置20使用在第k(=1~4)區域Ak內使用之讀頭60k-1、60k、60k+2(稱第k讀頭群)之測量值求出晶圓載台WST1之位置(Xk、Yk、θzk)。主控制裝置20求出從第k(=2~4)讀頭群之測量值算出之位置(Xk、Yk)相對從第1讀頭群之測量值算出之位置(X1、Y1)之偏差、亦亦即求出偏移(OXk=Xk-X1、OYk=Yk-Y1)。 First, as shown in FIG. 8 (A), the main control device 20 positions the wafer stage WST1 (WST2) in the area A 0 . In FIG. 8 (A), the wafer stage WST1 is positioned in the center of the area A 0 (immediately below the projection optical system PL). In the area A 0 , the read heads 60 1 to 60 4 mounted on the wafer stage WST1 are all opposed to the scale plate 21 (corresponding portions 21 1 to 21 4 ), and the effective measurement values are sent to the main control device 20. The main control device 20 uses the measured values of the read heads 60 k-1 , 60 k , and 60 k + 2 (referred to as the k-th read head group) used in the k (= 1 to 4) area Ak to obtain the wafer stage. The position of WST1 (X k , Y k , θz k ). The main control device 20 obtains the positions (X k , Y k ) calculated from the measurement values of the k-th (= 2 ~ 4) head group relative to the positions (X 1 , Y 1 ) calculated from the measurement values of the first head group ), That is, the offset (O Xk = X k- X 1 , O Yk = Y k- Y 1 ).
又,亦可與偏移(OXk、OYk)一起求出針對旋轉θz之偏移(Oθzk=θzk-θz1)。此場合,省略後述偏移Oθzk之算出。 Also, the offset (O θzk = θz k- θz 1 ) with respect to the rotation θz may be obtained together with the offset (O Xk , O Yk ). In this case, calculation of the offset O θzk described later is omitted.
上述求出之偏移(OXk、OYk)係用以將從第k(=2~4)讀頭群之測量值算出之位置(Xk、Yk)修正為(Xk-OXk、Yk-OYk)。藉由此修正,如圖8(B)所示,第k基準座標系Ck(=2~4)之原點Ok即與第1基準座標系C1之原點O1一致。圖中,彼此一致之原點以符號O表示。 The offsets (O Xk , O Yk ) obtained above are used to correct the positions (X k , Y k ) calculated from the measured values of the kth (= 2 ~ 4) reader group to (X k- O Xk , Y k- O Yk ). By this correction, as shown in FIG. 8 (B), the origin O k of the k-th reference coordinate system C k (= 2 ~ 4) is consistent with the origin O 1 of the first reference coordinate system C 1 . In the figure, the origins that coincide with each other are indicated by the symbol O.
接著,主控制裝置20,如圖8(C)所示,根據作為校正基準之從第1讀頭群之測量值算出之載台位置(X1、Y1、θz1),將晶圓載台WST1在區域A0內驅動於箭頭方向(X軸方向及Y軸方向),一邊每隔一既定間距進行定位、一邊使用四個讀頭群之測量值求出四個晶圓載台WST1之位置(Xk、Yk(k=1~4))。 Next, as shown in FIG. 8 (C), the main control device 20 sets the wafer stage based on the stage position (X 1 , Y 1 , θz 1 ) calculated from the measurement value of the first read head group as a calibration reference. WST1 is driven in the arrow direction (X-axis direction and Y-axis direction) in the area A 0. While positioning at every predetermined pitch, the positions of the four wafer stages WST1 are obtained using the measured values of the four read head groups ( X k , Y k (k = 1 ~ 4)).
主控制裝置20使用上述求出之四個載台位置(Xk、Yk(k=1~4))以例如最小平方運算決定偏移Oθzk,以使平方誤差εk=Σ((ξk-X1)2+(ζk-Y1)2)為最小。其中,k=2~4。(ξk、ζk)係使用次式(5)加以旋轉轉換之載台位置(Xk、Yk(k=2~4))。此處,為求出偏移Oθzk,雖係使用最小平方法為例,但不限於此,亦可使用最小平方法以外之運算手法。 The main control device 20 uses the four stage positions (X k , Y k (k = 1 ~ 4)) obtained as described above to determine an offset O θzk by , for example, a least square operation, so that the square error ε k = Σ ((ξ k- X 1 ) 2 + (ζ k- Y 1 ) 2 ) is the smallest. Among them, k = 2 ~ 4. (ξ k , ζ k ) are stage positions (X k , Y k (k = 2 ~ 4)) which are transformed by rotation using the following formula (5). Here, in order to obtain the offset O θzk , although the least square method is used as an example, it is not limited to this, and calculation methods other than the least square method may be used.
上述求出之偏移Oθzk,係用於將從第k(=2~4)讀頭群之測量值算出之旋轉θzk修正為θzk-Oθzk。藉由此修正,如圖8(D)所示,第k基準座標系Ck(=2~4)之方向(旋轉)即與第1基準座標系C1之方向(旋轉)一致。 The offset O θzk obtained above is used to correct the rotation θz k calculated from the measurement values of the k - th (= 2 ~ 4) head group to θz k- O θzk . With this correction, as shown in FIG. 8 (D), the direction (rotation) of the k-th reference coordinate system C k (= 2 to 4) is the same as the direction (rotation) of the first reference coordinate system C 1 .
其次,主控制裝置20與先前同樣的,如圖8(E)所示,根據載台位置(X1、Y1、θz1)將晶圓載台WST1在區域A0內驅動於箭頭方向(X軸方向及Y軸方向),一邊每隔既定間距進行定位、一邊求出四個晶圓載台WST1之位置(Xk、Yk(k=1~4))。 Next, as shown in FIG. 8 (E), the main control device 20 drives the wafer stage WST1 in the direction of the arrow (X) in the area A 0 according to the stage position (X 1 , Y 1 , θz 1 ). Axis direction and Y axis direction), while positioning at predetermined intervals, the positions (X k , Y k (k = 1 to 4)) of the four wafer stages WST1 are obtained.
主控制裝置20使用上述求出之四個載台位置(Xk、Yk(k=1~4)),以最小平方運算決定定標(ΓXk、ΓYk)以使平方誤差εk=Σ((ξk’-X1)2+(ζk’-Y1)2)為最小。其中,k=2~4。此處,(ξk’、ζk’)係使用次式(6)加以標尺轉換之載台位置(Xk、Yk(k=2~4))。 The main control device 20 uses the four stage positions (X k , Y k (k = 1 ~ 4)) obtained above, and determines the scaling (Γ Xk , Γ Yk ) by the least square operation so that the square error ε k = Σ ((ξ k '-X 1 ) 2 + (ζ k ' -Y 1 ) 2 ) is the smallest. Among them, k = 2 ~ 4. Here, (ξ k ', ζ k ') are the stage positions (X k , Y k (k = 2 ~ 4)) converted by the scale using the equation (6).
上述求出之定標(ΓXk、ΓYk)係用於將從第k(=2~4)讀頭群之測量值算出之位置(Xk、Yk)修正為(Xk/(1+ΓXk)、Yk/(1+ΓYk))。藉由此修正,如圖8(F)所示,第k基準座標系Ck(=2~4)之定標即與第1基準座標系C1之定標一致。 The calibrations (Γ Xk and Γ Yk ) obtained above are used to correct the positions (X k , Y k ) calculated from the measured values of the kth (= 2 ~ 4) head group to (X k / (1 + Γ Xk ), Y k / (1 + Γ Yk )). With this correction, as shown in FIG. 8 (F), the calibration of the k-th reference coordinate system C k (= 2 ~ 4) is consistent with the calibration of the first reference coordinate system C 1 .
藉由以上處理,旋轉及定標經校正之四個基準座標系C1~C4即被統合為涵蓋曝光時移動區域A0~A4之一個座標系(統合座標系)CE。 Through the above processing, the four reference coordinate systems C 1 to C 4 that have been rotated and calibrated are integrated into one coordinate system (combined coordinate system) C E that covers the moving area A 0 to A 4 during exposure.
又,亦可取代以上處理,藉由下述般之處理求出偏移及定標(OXk、OYk、Oθzk、ΓXk、ΓYk(k=2~4))。亦即,主控制裝置20,如圖8(C)或圖8(E)所示,根據載台位置(X1、Y1、θz1)將晶圓載台WST1在區域A0內驅動於箭頭方向(X軸方向及Y軸方向),一邊每隔既定間距進行定位、一邊求出四個晶圓載台WST1之位置(Xk、Yk(k=1~4))。主控制裝置20使用求出之四個 載台位置(Xk、Yk(k=1~4)),以最小平方運算決定偏移及定標(OXk、OYk、Oθzk、ΓXk、ΓYk),以使平方誤差εk=Σ((ξ”k-X1)2+(ζ”k-Y1)2)為最小。其中,k=2~4。此處,(ξ”k、ζ”k)係使用次式(7)進行轉換之載台位置(Xk、Yk(k=2~4))。 Instead of the above processing, the offset and calibration (O Xk , O Yk , O θzk , Γ Xk , Γ Yk (k = 2 to 4)) may be obtained by the following processing. That is, as shown in FIG. 8 (C) or FIG. 8 (E), the main control device 20 drives the wafer stage WST1 to the arrow in the area A 0 according to the stage position (X 1 , Y 1 , θz 1 ). In the directions (X-axis direction and Y-axis direction), the positions of the four wafer stages WST1 (X k , Y k (k = 1 to 4)) are obtained while positioning at predetermined intervals. The main control device 20 determines the offset and calibration (O Xk , O Yk , O θzk , Γ Xk ) by using the obtained four stage positions (X k , Y k (k = 1 ~ 4)) using a least square operation. , Γ Yk ) so that the square error ε k = Σ ((ξ ” k- X 1 ) 2 + (ζ” k- Y 1 ) 2 ) is minimized. Among them, k = 2 ~ 4. Here, (ξ ” k , ζ” k ) are stage positions (X k , Y k (k = 2 ~ 4)) which are converted using the equation (7).
又,上述處理雖係以第1基準座標系C1為基準直接求出針對第2~第4基準座標系C2~C4之偏移及定標,但亦可以間接方式求出。例如,依循上述程序求出針對以第1基準座標系C1為基準之第2基準座標系C2之偏移及定標(OX2、OY2、Oθz2、ΓX2、ΓY2)。同樣的,求出針對以第2基準座標系C2為基準之第3基準座標系C3之偏移及定標(OX32、OY32、Oθz32、ΓX32、ΓY32)。從此等之結果,針對以第1基準座標系C1為基準之第3基準座標系C3之偏移及定標即被求出為(OX3=OX32+OX2、OY3=OY32+OY2、Oθz3=Oθz32+Oθz2、ΓX3=ΓX32‧ΓX2、ΓY3=ΓY32‧ΓY2)。同樣的,亦可求出針對以第3基準座標系C3為基準之第4基準座標C4之偏移及定標,使用其結果求出針對以第1基準座標C1為基準之第4基準座標C4之偏移及定標。 In addition, although the above-mentioned processing is to directly obtain the offset and calibration for the second to fourth reference coordinate systems C 2 to C 4 using the first reference coordinate system C 1 as a reference, it may also be obtained indirectly. For example, follow the procedure described above for obtaining the first reference coordinate system as a reference of a C 2 C 2 of the reference coordinate system offsets and scaling (O X2, O Y2, O θz2, Γ X2, Γ Y2). Similarly, the offset and calibration (O X32 , O Y32 , O θz32 , Γ X32 , Γ Y32 ) for the third reference coordinate system C 3 based on the second reference coordinate system C 2 is obtained. From this result, etc., for the first reference coordinate system as a reference of a C 3 C 3 of the reference coordinate system and the scaling i.e. offset is determined (O X3 = O X32 + O Y3 = O Y32 X2, O + O Y2 , O θz3 = O θz32 + O θz2 , Γ X3 = Γ X32 ‧Γ X2 , Γ Y3 = Γ Y32 ‧Γ Y2 ). Similarly, the offset and calibration of the fourth reference coordinate C 4 based on the third reference coordinate system C 3 can be obtained, and the fourth reference coordinate C 4 based on the first reference coordinate C 1 can be used as a result to calculate the offset and calibration. Offset and calibration of the reference coordinate C 4 .
主控制裝置20針對標尺板22亦係依循同様程序校正四個基準座標,將之統合為涵蓋測量時移動區域之一個座標系(統合座標系)CA(參照圖7(B))。 Main controller 20 also lines follow the correct four reference coordinates with Yang procedure for the scale plate 22, to the integration a coordinate system (unified coordinate system) movement area when covered measured C A (see FIG. 7 (B)).
最後,主控制裝置20,求出涵蓋曝光時移動區域A0~A4之統合座標系CE與涵蓋測量時移動區域之統合座標系CA間之位置、旋轉、定標之偏差。主控制裝置20,如圖9(A)所示,使用編碼器系統70求出(測量)晶圓載台WST1之位置資訊,根據其結果驅動晶圓載台WST1,將晶圓台WTB1上之第1基準標記板FM1定位在投影光學系PL正下方(曝光中心P)。主控制裝置20使用一對標線片對準系13A、13B檢測第1基準標記板FM1上形成 之二個(一對)基準標記。其次,主控制裝置20根據編碼器系統70之測量結果驅動晶圓載台WST1,將晶圓台WTB1上之第2基準標記板FM2定位在投影光學系PL正下方(曝光中心P),使用一對標線片對準系13A、13B之任一者檢測第2基準標記板FM2上形成之一個基準標記。主控制裝置20從三個基準標記之檢測結果(亦即,三個基準標記之二維位置座標)求出統合座標系CE之原點之位置、旋轉、定標。 Finally, the main control device 20 obtains deviations in position, rotation, and calibration between the integrated coordinate system C E covering the moving area A 0 to A 4 during exposure and the integrated coordinate system C A covering the moving area during measurement. As shown in FIG. 9 (A), the main control device 20 obtains (measures) the position information of the wafer stage WST1 using the encoder system 70, drives the wafer stage WST1 based on the result, and sets the first stage on the wafer stage WTB1. The reference mark plate FM1 is positioned directly below the projection optical system PL (exposure center P). The main control device 20 detects two (pair) reference marks formed on the first reference mark plate FM1 using a pair of reticle alignment systems 13A and 13B. Next, the main control device 20 drives the wafer stage WST1 according to the measurement result of the encoder system 70, and positions the second reference mark plate FM2 on the wafer stage WTB1 directly below the projection optical system PL (exposure center P). The reticle alignment system 13A or 13B detects a reference mark formed on the second reference mark plate FM2. Main controller 20 obtains the position of the origin of the coordinate system C E integration from the detection result of (i.e., three-dimensional position coordinates of the reference mark) of the three reference markers, rotation, scaling.
主控制裝置20將晶圓載台WST1移動至測量時移動區域。此時,主控制裝置20在曝光時移動區域A0~A4與測量時移動區域之間之區域內係使用晶圓干涉儀系統18、測量時移動區域內則使用編碼器系統70測量晶圓載台WST1之位置資訊,根據其結果進行晶圓載台WST1之驅動(位置控制)。移動後,主控制裝置20,如圖10(A)及圖10(B)所示,使用對準系ALG與先前同樣的檢測三個基準標記,從其檢測結果求出統合座標系CA之原點之位置、旋轉、定標。又,作為標線片對準系13A、13B之檢測對象之三個基準標記與作為對準系ALG之檢測對象之三個基準標記,雖以同一標記較佳,但在無法以標線片對準系13A、13B與對準系ALG檢測同一基準標記之情形時,由於已知基準標記彼此之位置關係,因此標線片對準系13A、13B與對準系ALG可以不同基準標記為檢測對象。 The main control device 20 moves the wafer stage WST1 to a moving area during measurement. At this time, the main control device 20 uses the wafer interferometer system 18 in the area between the moving areas A 0 to A 4 during exposure and the moving area during measurement, and uses the encoder system 70 to measure the wafer load in the moving area during measurement. Based on the position information of the stage WST1, the wafer stage WST1 is driven (position control). After the movement, as shown in FIG. 10 (A) and FIG. 10 (B), the main control device 20 uses the alignment system ALG to detect three reference marks the same as before, and obtains the coordinate system C A from the detection results. Origin position, rotation, calibration. In addition, although the three reference marks used as the detection targets of the alignment system 13A and 13B and the three reference marks used as the detection objects of the alignment system ALG, although the same mark is preferred, it is impossible to use the reticle to When the alignment system 13A, 13B and the alignment system ALG detect the same reference mark, the positional relationship between the reference marks is known. Therefore, the reticle alignment system 13A, 13B and the alignment system ALG can be different reference marks for detection. .
又,在晶圓載台於曝光時移動區域與測量時移動區域之間移動之情形時,亦可使用編碼器系統進行晶圓載台之位置控制。於曝光時移動區域內、測量時移動區域內分別進行接續處理(相位接續及/或座標接續)。此處,座標接續係指在切換編碼器(讀頭)之前與後,為使算出之晶圓載台WST之位置座標完全一致,而設定對切換後使用之編碼器之測量值,與此時再設定相位偏移之接續處理。相位接續法則係指基本上雖與座標接續法相同,但相位偏移之處理之不同,不進行相位偏移之再設定,而繼續使用已設定之相位偏移,僅再設定計數值之接續法。 In addition, when the wafer stage moves between the moving region during exposure and the moving region during measurement, the encoder system can also be used to control the position of the wafer stage. The splicing process (phase splicing and / or coordinate splicing) is performed in the moving area during exposure and the moving area during measurement, respectively. Here, the coordinate connection means that before and after the encoder (reading head) is switched, in order to make the calculated position coordinates of the wafer stage WST completely consistent, the measured value of the encoder used after the switch is set, and then again Set the continuation processing of phase shift. The phase continuity rule refers to the continuation method that is basically the same as the coordinate continuation method, but the processing of the phase shift is different. The phase offset is not reset, and the set phase offset is continued. Only the count value is set. .
主控制裝置20,從上述求出之統合座標系CE之原點之位置、旋轉、定標與統合座標系CA之原點之位置、旋轉、定標,求出統合座標系CE、CA間之原點、旋轉、定標之偏差。主控制裝置20可使用此偏差,例如將於統合座標系CA上測量之晶圓對準結果、例如晶圓上複數個照射區域之排列座標(或晶圓上對準標記之位置座標)轉換為在統合座標系CE上之晶圓上複數個照射區域之排列座標,根據該轉換後之排列座標,於晶圓之曝光動作時在統合座標CE系上進行晶圓載台WST1之驅動(位置控制)。 Main controller 20, from the position of the origin of the integration of the above obtained coordinate system C E, the rotation, scaling and position of the origin of the coordinate system and integration of C A, rotation, scaling, integration obtains coordinate system C E, C A deviation between origin, rotation, and calibration. Main controller 20 may use the deviation, e.g. the wafer alignment measurement result will be on the integration coordinate system C A, for example, the arrangement coordinates of a plurality of shot areas (or the alignment mark on the wafer coordinate positions) on the wafer Conversion plural arrangement coordinates of shot area on the integration of the wafer on the coordinate system C E, according to the arrangement coordinates rear of the conversion, when the exposure operation of a wafer of wafer stage WST1 of the drive on the unified coordinate C E system ( Position control).
主控制裝置20係在每一晶圓之曝光處理(或每隔既定片數晶圓之曝光處理)進行上述校正方法。亦即,在進行使用對準系ALG之晶圓對準前,如前所述,校正使用標尺板22時之編碼器系統70、71(將四個基準座標系C1~C4統合為統合座標系CA)。使用經校正之編碼器系統70、71(在統合座標系CA上)對曝光對象之晶圓進行晶圓對準等之測量動作。接著,於晶圓之曝光處理前,如前所述,校正使用標尺板21時之編碼器系統70、71(將四個基準座標系C1~C4統合為統合座標系CE)。又,求出統合座標系CA、CE間之位置、旋轉、定標之偏差(相對位置、相對旋轉、相對定標)。使用此等結果將在統合座標系CA上測量之晶圓對準結果(例如晶圓上複數個照射區域之排列座標)轉換為在統合座標系CE上之晶圓上複數個照射區域之排列座標,根據該轉換後之排列座標,在統合座標系CE上進行保持晶圓之晶圓載台WST1、WST2之驅動(位置控制)以進行晶圓之曝光處理。 The main control device 20 performs the above-mentioned correction method in the exposure process of each wafer (or the exposure process every predetermined number of wafers). That is, before performing wafer alignment using the alignment system ALG, as described above, the encoder systems 70 and 71 (using the four reference coordinate systems C 1 to C 4 when the scale plate 22 is used are integrated into a unified system. The coordinate system is C A ). Corrected using the encoder system 70 and 71 (in the unified coordinate system C A) of the wafer subject to exposure of wafer alignment measurement operation of the like. Next, before the wafer exposure processing, as described above, the encoder systems 70 and 71 (the four reference coordinate systems C 1 to C 4 are integrated into the unified coordinate system C E ) when the scale plate 21 is used. In addition, the deviations (relative position, relative rotation, and relative calibration) of the position, rotation, and calibration between the integrated coordinate systems C A and C E are obtained. Use these results to convert the wafer alignment results measured on the integrated coordinate system C A (such as the alignment coordinates of the plurality of illuminated areas on the wafer) into the multiple illuminated areas on the wafer on the integrated coordinate system C E arrangement coordinates, according to the arrangement of the coordinates after the conversion, the wafer holding wafer stage WST1, WST2 the drive (position control) to carry out exposure processing on the wafer coordinate system integration C E.
又,作為校正處理(校正方法),雖可修正編碼器系統之測量值,但亦可採用其他處理。例如,亦可適用將該測量誤差作為偏移於晶圓載台之現在位置或目標位置加入偏移,以進行晶圓載台之驅動(位置控制)、或將標線片位置僅修正該測量誤差分等之其他手法。 In addition, as the correction process (correction method), although the measurement value of the encoder system can be corrected, other processes can also be adopted. For example, the measurement error can also be applied as an offset from the current position or target position of the wafer stage to drive the wafer stage (position control), or the position of the reticle can only correct the measurement error. And other methods.
接著,進一步說明以編碼器系統70、71進行之3自由度方向(Z、θx、θy)之位置測量原理等。此處,編碼器讀頭601~604或編碼器701~704之測 量結果或測量值,係指編碼器讀頭601~604或編碼器701~704之Z軸方向之測量結果。 Next, the principle of position measurement in the three-degree-of-freedom directions (Z, θx, θy) performed by the encoder systems 70 and 71 will be further described. Here, the encoder 1 to the read head 60 measured by the encoder 604 or 701 ~ 704 or the result of measurements, the read head 60 refers to the encoder 1 to the encoder 604 or the Z-axis direction of 701 ~ 704 The measurement results.
本實施形態,由於採用了如前述之編碼器讀頭601~604及標尺板21之構成及配置,在曝光時移動區域內,依據晶圓載台WST1(WST2)所在之區域A0~A4,編碼器讀頭601~604中之至少三個與標尺板21(之對應部分211~214)對向。從與標尺板21對向之讀頭(編碼器)將有效測量值送至主控制裝置20。 In this embodiment, because the structure and arrangement of the encoder read heads 60 1 to 60 4 and the scale plate 21 are used as described above, the moving area during exposure is based on the area A 0 ~ A where the wafer stage WST1 (WST2) is located. 4 , at least three of the encoder reading heads 60 1 to 60 4 are opposed to the scale plate 21 (the corresponding portions 21 1 to 21 4 ). The effective measurement value is sent from the read head (encoder) facing the scale plate 21 to the main control device 20.
主控制裝置20根據編碼器701~704(或711~714)之測量結果算出晶圓載台WST1(WST2)之位置(Z、θx、θy)。此處,編碼器701~704(或711~714)於Z軸方向之測量值(非前述Z軸方向之測量方向,亦即與針對XY平面內之一軸方向之測量值C1~C4作出區別,分別記載為D1~D4),係如次式(8)~(11)般依存於晶圓載台WST1(WST2)之位置(Z、θx、θy)。 The main control device 20 calculates the positions (Z, θx, θy) of the wafer stage WST1 (WST2) based on the measurement results of the encoders 70 1 to 70 4 (or 71 1 to 71 4 ). Here, the measured value of the encoder 70 1 to 70 4 (or 71 1 to 71 4 ) in the Z axis direction (not the measurement direction of the aforementioned Z axis direction, that is, the measured value C 1 with respect to an axis direction in the XY plane) ~ C 4 is distinguished and is described as D 1 ~ D 4 respectively, and depends on the positions (Z, θx, θy) of the wafer stage WST1 (WST2) like the following equations (8) to (11).
D1=-ptanθy+ptanθx+Z...(8) D 1 = -ptanθy + ptanθx + Z ... (8)
D2=ptanθy+ptanθx+Z...(9) D 2 = ptanθy + ptanθx + Z ... (9)
D3=ptanθy-ptanθx+Z...(10) D 3 = ptanθy-ptanθx + Z ... (10)
D4=-ptanθy-ptanθx+Z...(11) D 4 = -ptanθy-ptanθx + Z ... (11)
其中,p係從晶圓台WTB1(WTB2)之中心至讀頭之X軸及Y軸方向之距離(參照圖5)。 Among them, p is the distance from the center of the wafer table WTB1 (WTB2) to the X-axis and Y-axis directions of the read head (see FIG. 5).
主控制裝置20依據晶圓載台WST1(WST2)所在之區域A0~A4從上式(8)~(11)選擇三個讀頭(編碼器)之測量值依據之式,藉由將三個讀頭(編碼器)之測量值代入以解由所選擇之三個式構成之連立方程式,據以算出晶圓載台WST1(WST2)之位置(Z、θx、θy)。例如,晶圓載台WST1(或WST2)位於第1區域A1內之情形時,主控制裝置20由讀頭601、602、604(編碼器701、702、704或711、712、714)之測量值依據之式(8)、(9)及(11)組合連立方程式,將測量值代入式(8)、(9)及(11)各式之左邊以解之。將算出之位置(Z、θx、θy) 記載為Z1、θx1、θy1。同樣的,主控制裝置20在晶圓載台WST1位於第k區域Ak內之情形時,從讀頭60k-1、60k、60k+1(編碼器70k-1、70k、70k+1)之測量值所依據之式((k-1)+7)、(k+7)及((k+1)+7)組合連立方程式,將各讀頭之測量值代入式((k-1)+7)、(k+7)及((k+1)+7)各自之左邊以解連立方程式。據此,算出位置(Zk、θxk、θyk)。此處,於k-1、k及k+1係代入週期性置換1~4之數。 The main control device 20 selects three reading heads (encoders) based on the formulas based on the areas A 0 ~ A 4 where the wafer stage WST1 (WST2) is located. The measured values of the read heads (encoders) are substituted to solve the simultaneous equations composed of the three selected equations, and the positions (Z, θx, θy) of the wafer stage WST1 (WST2) are calculated. For example, when the wafer stage WST1 (or WST2) is located in the first area A 1 , the main control device 20 is controlled by the read heads 60 1 , 60 2 , 60 4 (encoders 70 1 , 70 2 , 70 4 or 71 1 , 71 2 , 71 4 ) The measured values are based on equations (8), (9), and (11) combined with simultaneous equations, and the measured values are substituted into the left side of the equations (8), (9), and (11) to solve Of it. The calculated positions (Z, θx, θy) are described as Z 1 , θx 1 , θy 1 . Similarly, when the wafer stage WST1 is located in the k-th area Ak , the main control device 20 slaves the read heads 60 k-1 , 60 k , 60 k + 1 (encoders 70 k-1 , 70 k , 70 k + 1 ) is based on the formula ((k-1) +7), (k + 7) and ((k + 1) +7) combined simultaneous equations, and the measured value of each read head is substituted into the formula ( (k-1) +7), (k + 7), and ((k + 1) +7) are left to solve the simultaneous equations. Based on this, the positions (Z k , θx k , θy k ) are calculated. Here, the numbers 1 to 4 are substituted for k-1, k, and k + 1.
又,當晶圓載台WST1(或WST2)位置第0區域A0內之情形時,從讀頭601~604(編碼器701~704或711~714))選擇任意三個,使用由所選擇之三個讀頭之測量值依據之式組合之連立方程式即可。 When the wafer stage WST1 (or WST2) is located in the 0th area A 0 , select any three from the read heads 60 1 to 60 4 (encoders 70 1 to 70 4 or 71 1 to 71 4 ). Use the simultaneous equations that are based on the combination of the measured values of the three read heads selected.
主控制裝置20根據上述算出結果(Z、θx、θy)與前述段差資訊(focus mapping data),於曝光時移動區域內進行晶圓載台WST1(或WST2)聚焦調平控制。 The main control device 20 performs focus leveling control of the wafer stage WST1 (or WST2) in the moving area during exposure based on the calculation results (Z, θx, θy) and the aforementioned focus mapping data.
當晶圓載台WST1(或WST2)位於測量時移動區域內之情形時,主控制裝置20使用編碼器系統70(或71)測量晶圓載台WST1(或WST2)之3自由度方向(Z、θx、θy)之位置資訊。此處,測量原理等,除曝光中心換為對準系ALG之檢測中心、標尺板21(之部分211~214)換為標尺板22(之部分221~224)外,與晶圓載台WST1位於之前之曝光時移動區域內之情形相同。主控制裝置20根據編碼器系統70或71之測量結果,進行晶圓載台WST1或WST2之聚焦調平控制。又,於測量時移動區域(測量站)亦可不進行聚焦、調平。亦即,先取得標記位置及段差資訊(focus mapping data),並從該段差資訊減去段差資訊取得時(測量時)之晶圓載台之Z傾斜分,據以取得晶圓載台之基準面、例如以上面為基準之段差資訊。於曝光時,根據此段差資訊與晶圓載台(之基準面)之3自由度方向(Z、θx、θy)之位置資訊,即能進行聚焦、調平。 When the wafer stage WST1 (or WST2) is located in the moving area during measurement, the main control device 20 uses the encoder system 70 (or 71) to measure the 3 degree of freedom direction (Z, θx) of the wafer stage WST1 (or WST2). , Θy). Here, the measurement principle, etc., except that the exposure center is changed to the detection center of the alignment system ALG, and the ruler plate 21 (part 21 1 to 21 4 ) is replaced to the ruler plate 22 (part 22 1 to 22 4 ). The situation is the same when the circular stage WST1 is located in the moving area during the previous exposure. The main control device 20 performs focus leveling control of the wafer stage WST1 or WST2 according to the measurement result of the encoder system 70 or 71. It is also possible to move the area (measuring station) during measurement without focusing or leveling. That is, the mark position and focus mapping data are first obtained, and the Z-slope of the wafer stage when the stage difference information is obtained (at the time of measurement) is subtracted from the stage difference information, thereby obtaining the reference plane of the wafer stage, For example, step information based on the above. During exposure, focusing and leveling can be performed based on the difference information and the position information in the 3 degrees of freedom (Z, θx, θy) of the wafer stage (reference plane).
進一步的,主控制裝置20依據晶圓載台WST1、WST2之位置,將與 標尺板21、22對向之讀頭601~604中之三個換為至少一個不同之三個來使用。此處,於切換編碼器讀頭時,為確保晶圓載台WST1(或WST2)之位置測量結果之連續性,進行與前述相同之接續處理。 Further, according to the positions of the wafer stages WST1 and WST2, the main control device 20 replaces three of the read heads 60 1 to 60 4 opposite to the scale plates 21 and 22 with at least one different three for use. Here, when the encoder read head is switched, in order to ensure the continuity of the position measurement result of the wafer stage WST1 (or WST2), the same continuation processing as described above is performed.
如前所述,本實施形態之曝光裝置100中之標尺板21、22係分別由四個部分211~214、221~224構成。此處,四個部分之高度與傾斜彼此偏差時,即會產生編碼器系統70、71之測量誤差。因此,適用與先前相同之校正方法,校正因部分211~214或221~224彼此間之高度與傾斜之偏差造成之四個基準座標系C1~C4彼此間之偏差。 As described above, the scale plates 21 and 22 in the exposure apparatus 100 of this embodiment are respectively composed of four sections 21 1 to 21 4 and 22 1 to 22 4 . Here, when the height and tilt of the four parts deviate from each other, a measurement error of the encoder systems 70 and 71 will occur. Therefore, the same correction method as before is applied to correct the deviations of the four reference coordinate systems C 1 to C 4 caused by the deviations of the height and inclination of the sections 21 1 to 21 4 or 22 1 to 22 4 .
此處,以使用編碼器系統70之情形為例,說明校正方法之一例。 Here, an example of a correction method will be described using a case where the encoder system 70 is used.
主控制裝置20,如圖8(C)或圖8(E)所示,根據以編碼器系統70測量之晶圓載台WST1之位置之測量結果(X1、Y1、θz1),將晶圓載台WST1在區域A0內驅動於箭頭方向(X軸方向及Y軸方向),一邊每隔既定間距進行定位、一邊使用四個讀頭群之測量值求出四個晶圓台WTB1之位置(Zk、θxk、θyk(k=1~4))。主控制裝置20使用此等結果,求出從第k(=2~4)讀頭群之測量值算出之位置(Zk、θxk、θyk)相對於從第1讀頭群之測量值算出之位置(Z1、θx1、θy1)之偏差、亦即求出偏移(OZk=Zk-Z1、Oθxk=θxk-θx1、Oθyk=θyk-θy1)。進一步的,主控制裝置20將每次定位求出之偏移(OZk、Oθxk、Oθyk)加以平均。 The main control device 20, as shown in FIG. 8 (C) or FIG. 8 (E), based on the measurement results (X 1 , Y 1 , θz 1 ) of the position of the wafer stage WST1 measured by the encoder system 70. The circular stage WST1 is driven in the direction of the arrow (X-axis direction and Y-axis direction) in the area A 0 , and the positions of the four wafer tables WTB1 are obtained using the measured values of the four read head groups while positioning at predetermined intervals. (Z k , θx k , θy k (k = 1 ~ 4)). The main control device 20 uses these results to find the position (Z k , θx k , θy k ) calculated from the measurement values of the k- th (= 2 ~ 4) head group relative to the measurement values from the first head group The deviation of the calculated position (Z 1 , θx 1 , θy 1 ), that is, the offset (O Zk = Z k- Z 1 , O θxk = θx k- θx 1 , O θyk = θy k- θy 1 ) . Further, the main control device 20 averages the offsets (O Zk , O θxk , O θyk ) obtained for each positioning.
上述求出之偏移(OZk、Oθxk、Oθyk)係用於將從第k(=2~4)讀頭群之測量值算出之位置(Zk、θxk、θyk)分別修正為Zk-OZk、θxk-Oθxk、θyk-Oθyk。藉由此修正,第k基準座標系Ck(k=2~4)之高度Z與傾斜θx、θy即與第1基準座標系C1之高度Z與傾斜θx、θy一致。亦即,四個基準座標系C1~C4被統合為涵蓋曝光時移動區域A0~A4之一個座標系(統合座標系)CE。 The offsets (O Zk , O θxk , O θyk ) obtained above are used to correct the positions (Z k , θx k , θy k ) calculated from the measured values of the kth (= 2 ~ 4) group of read heads, respectively. It is Z k- O Zk , θx k- O θxk , θy k- O θyk . With this correction, the height Z and the inclination θx, θy of the k-th reference coordinate system C k (k = 2 to 4) are consistent with the height Z and the inclination θx, θy of the first reference coordinate system C 1 . That is, the four reference coordinate systems C 1 to C 4 are integrated into one coordinate system (integrated coordinate system) C E that covers the moving areas A 0 to A 4 during exposure.
主控制裝置20,針對編碼器系統71亦依循同様程序校正四個基準座標,將之統合為涵蓋測量時移動區域之一個座標系(統合座標系)CA。 Main controller 20, the correction also follow the same four reference coordinates Yang encoder system 71 for the program, the integration of a coordinate system (coordinate system integration) moves to cover the measurement area when C A.
主控制裝置20,與先前同樣的,在每一晶圓之曝光處理(或每既定片數之晶圓之曝光處理)進行上述校正方法。亦即,在使用對準系ALG之晶圓對準前,如前所述,對使用標尺板22時之編碼器系統70(或71)進行校正(將四個基準座標系C1~C4統合為統合座標系CA)。主控制裝置20並使用經校正之編碼器系統70(或71)(在統合座標系CA上)對曝光對象之晶圓進行晶圓對準。接著,主控制裝置20在晶圓之曝光處理前,如前所述,對使用標尺板21時之編碼器系統70(或71)進行校正(將四個基準座標系C1~C4統合為統合座標系CE)。主控制裝置20並使用經校正之編碼器系統70(或71)(在統合座標系CE上)求出(測量)保持晶圓之晶圓台WTB1(或WTB2)之位置資訊,根據該測量結果與晶圓對準之結果,於晶圓之曝光時,進行晶圓台WTB1(或WTB2)之驅動(位置控制)。 The main control device 20 performs the above-mentioned correction method in the exposure process of each wafer (or the exposure process of a predetermined number of wafers) as before. That is, before the wafer alignment using the alignment system ALG, as described above, the encoder system 70 (or 71) using the scale plate 22 is calibrated (the four reference coordinate systems C 1 to C 4 Unification is the unified coordinate system C A ). Main controller 20 and corrected using the encoder system 70 (or 71) (in the unified coordinate system C A) of the wafer subject to exposure of wafer alignment performed. Next, before the wafer exposure processing, as described above, the main control device 20 corrects the encoder system 70 (or 71) when the scale plate 21 is used (the four reference coordinate systems C 1 to C 4 are integrated into Integrated coordinate system C E ). Main controller 20 and corrected using the encoder system 70 (or 71) (in the unified coordinate system C E) is determined (measured) WTBl wafer table holding wafer (or WTB2) the location information, based on the measurement As a result of the alignment with the wafer, the wafer table WTB1 (or WTB2) is driven (position control) during wafer exposure.
如以上之詳細說明,根據本實施形態之曝光裝置100,主控制裝置20在晶圓載台WST1、WST2上搭載之四個讀頭601~604中、包含互異之一個讀頭之三個讀頭所屬之第1讀頭群與第2讀頭群中所含之讀頭與標尺板21、22上對應之區域(部分211~214、221~224)對向之區域A0內,根據使用第1讀頭群所得之位置資訊進行晶圓載台WST1、WST2之驅動(位置控制),並使用以第1及第2讀頭群所得之位置資訊求出與第1及第2讀頭群分別對應之第1及第2基準座標系C1、C2間之偏差(位置、旋轉、定標之偏差)。主控制裝置20使用該結果修正使用第2讀頭群所得之測量結果,據以使第1及第2基準座標系C1、C2間之偏差獲得校正,而能修正四個讀頭601~604分別對向之標尺板21、22上之區域彼此間之偏差伴隨之測量誤差。 As described in detail above, according to the exposure apparatus 100 of this embodiment, the main control device 20 includes three read heads 60 1 to 60 4 mounted on the wafer stages WST1 and WST2, including three read heads that are different from each other. The area A opposite to the corresponding area (parts 21 1 to 21 4 , 22 1 to 22 4 ) on the scales 21 and 22 included in the first and second read groups to which the read head belongs Within 0 , the wafer stage WST1 and WST2 are driven (position control) based on the position information obtained using the first read head group, and the position information obtained using the first and second read head groups is used to obtain the first and second read positions. The two read head groups respectively correspond to the deviations (position, rotation, and calibration deviations) between the first and second reference coordinate systems C 1 and C 2 . The main control device 20 uses this result to correct the measurement results obtained by using the second read head group, so that the deviations between the first and second reference coordinate systems C 1 and C 2 can be corrected, and the four read heads 60 1 can be corrected. ~ 60 4 The measurement error accompanied by the deviation between the areas on the opposite scale plates 21 and 22 respectively.
又,根據本實施形態之曝光裝置100,由於係利用上述校正方法校正編碼器系統70、71,以修正四個基準座標系C1~C4彼此間之偏差,因此能使用編碼器系統70、71以高精度測量晶圓載台WST1、WST2之位置資訊並加以驅動(位置控制)。 In addition, according to the exposure apparatus 100 of this embodiment, the encoder systems 70 and 71 are corrected by using the above-mentioned correction method to correct the deviations between the four reference coordinate systems C 1 to C 4. Therefore, the encoder systems 70 and 70 can be used. 71 The position information of the wafer stages WST1 and WST2 is measured with high accuracy and driven (position control).
又,根據本實施形態之曝光裝置100,由主控制裝置20使用標線片對準系13A、13B及對準系ALG檢測晶圓載台WST1、WST2上所設之三個基準標記,據以求出分別對應曝光時移動區域、測量時移動區域之統合座標系CE、CA之相對位置、相對旋轉、相對定標。並可由主控制裝置20使用該結果,將在統合座標系CA上測量之晶圓對準之結果、例如將晶圓上複數個照射區域之排列座標轉換為在統合座標系CE上之晶圓上複數個照射區域之排列座標,使用該結果在統合座標CE上進行晶圓載台WST1、WST2之驅動(位置控制)以使晶圓曝光。 In addition, according to the exposure apparatus 100 of this embodiment, the main control device 20 uses the reticle alignment systems 13A and 13B and the alignment system ALG to detect three reference marks set on the wafer stages WST1 and WST2, and obtains the corresponding movement area exposure, measurement integration moving area coordinate system C E, C A relative position, the relative rotation, the relative scaling. And can be used by the main control unit 20 of the result of the measurement result in the integration C A wafer alignment coordinate system, the coordinate transformation, for example, the complex arrangement of the irradiation area as a crystal on a unified coordinate system C E of the wafer a complex array coordinates of the shot areas on a circle, using the result of wafer stage WST1 in the unified coordinate C E, WST2 the drive (position control) to the wafer exposure.
又,上述實施形態中,在晶圓載台WST1位於第0區域A0內時晶圓載台WST1上之所有讀頭601~604與標尺板21(對應之部分211~214)對向。因此,在第0區域A0內,係從所有讀頭601~604(編碼器701~704)將有效測量值送至主控制裝置20。因此,主控制裝置20亦可根據在四個讀頭601~604中、包含互異之一個讀頭之三個讀頭所屬之前述第k讀頭群(k=1~4)中所含之讀頭與標尺板21上之對應區域(部分211~214)對向之區域A0內,使用第k讀頭群(k=1~4)之至少一個所得之位置資訊、例如使用第1讀頭群所得之第1位置資訊與使用第2讀頭群所得之第2位置資訊之至少一方,進行晶圓載台WST1、WST2之驅動(位置控制)。此場合,即使與第1讀頭群及第2讀頭群對應之座標系(標尺板21之部分)不同,亦能在不受影響之情形下,高精度的驅動晶圓載台WST1、WST2。使用標尺板22之場合亦同。 In the above embodiment, when the wafer stage WST1 is located in the 0th area A 0 , all the read heads 60 1 to 60 4 on the wafer stage WST1 are opposed to the scale plate 21 (corresponding parts 21 1 to 21 4 ). . Therefore, in the 0th area A 0 , the effective measurement values are sent from all the read heads 60 1 to 60 4 (encoders 70 1 to 70 4 ) to the main control device 20. Therefore, the main control device 20 may also be based on the k-th read head group (k = 1 to 4) among the four read heads 60 1 to 60 4 including three read heads that are different from each other. The position information obtained by using at least one of the k-th read head group (k = 1 ~ 4) in the area A 0 opposite to the corresponding area (parts 21 1 to 21 4 ) of the read head and the scale plate 21, such as The at least one of the first position information obtained by the first read head group and the second position information obtained by the second read head group is used to drive (position control) the wafer stages WST1 and WST2. In this case, even if the coordinate system (the part of the scale plate 21) corresponding to the first read group and the second read group is different, the wafer stages WST1 and WST2 can be driven with high accuracy without being affected. The same applies when the ruler plate 22 is used.
又,上記實施形態中,因構成標尺板21、22之部分211~214、221~224彼此間之偏差造成之四個基準座標系C1~C4彼此間之偏差之校正處理,無須著眼於位置、旋轉、定標之全部,可以是其中之一者或任意二者,亦可追加或代用其他因素(正交度等)。 In the above embodiment, the correction process of the deviations of the four reference coordinate systems C 1 to C 4 caused by the deviations between the parts 21 1 to 21 4 and 22 1 to 22 4 constituting the scale plates 21 and 22 is different from each other. It is not necessary to focus on the position, rotation, and calibration. It can be one or any of them, and other factors (orthogonality, etc.) can be added or substituted.
又,上述實施形態,可分別接近晶圓台上面四角之讀頭設置至少一個 輔助讀頭,在主要讀頭發生測量異常時,切換為近旁之輔助讀頭來持續進行測量。此時,針對輔助讀頭亦可適用前述配置條件。 In addition, in the above embodiment, at least one of the read heads may be respectively arranged near the four corners of the upper surface of the wafer table. Auxiliary read head. When the main read head has an abnormal measurement, it switches to the nearby auxiliary read head for continuous measurement. At this time, the aforementioned arrangement conditions can also be applied to the auxiliary read head.
又,上述實施形態,雖係針對在標尺板21、22之部分211~214、221~224各個之下面形成有二維繞射光柵RG之情形作了例示,但不限於此,形成有僅以對應編碼器讀頭601~604之測量方向(在XY平面內之一軸方向)為週期方向之1維繞射光柵之場合,亦能適用上述實施形態。 In addition, the above-mentioned embodiment has exemplified the case where the two-dimensional diffraction grating RG is formed under each of the portions 21 1 to 21 4 and 22 1 to 22 4 of the scale plates 21 and 22, but it is not limited thereto. The above-mentioned embodiment can also be applied to a case where a one-dimensional diffraction grating is formed in which the measurement direction (one axis direction in the XY plane) corresponding to the encoder read heads 60 1 to 60 4 is a periodic direction.
又,上述實施形態,雖係針對根據在晶圓載台WST1、WST2上搭載之四個讀頭601~604中、包含互異之一個讀頭之三個讀頭所屬之第1讀頭群與第2讀頭群中所含之讀頭與標尺板21、22上對應之區域(部分211~214、221~224)對向之區域A0內,使用第1讀頭群所得之位置資訊進行晶圓載台WST1、WST2之驅動(位置控制),並使用以第1及第2讀頭群所得之位置資訊求出與第1及第2讀頭群分別對應之第1及第2基準座標系C1、C2間之偏差(位置、旋轉、定標之偏差),使用其結果修正使用第2讀頭群所得之測量結果,據以修正四個讀頭601~604分別對向之標尺板21、22上之區域彼此間之偏差所伴隨之測量誤差之情形作了說明,但不限於此,例如亦可以較用於晶圓載台之位置控制之複數(第1數)讀頭數量多之複數(第2數)讀頭在可分別進行位置測量之區域內移動晶圓載台,而取得以編碼器系統求出之載台位置資訊之修正資訊,亦即可在例如上述實施形態之十字區域A0內移動載台而使用冗長讀頭取得修正資訊。 The above-mentioned embodiment is directed to the first read head group to which three read heads including different read heads among four read heads 60 1 to 60 4 mounted on the wafer stages WST1 and WST2 belong. The first reader group is used in the area A 0 opposite to the area (parts 21 1 to 21 4 and 22 1 to 22 4 ) corresponding to the read heads included in the second reader group and the scale plates 21 and 22. The obtained position information is used to drive (position control) the wafer stages WST1 and WST2, and the position information obtained by the first and second read head groups is used to obtain the first and second read head groups corresponding to the first and second read head groups, respectively. The second reference coordinate is the deviation between C 1 and C 2 (the deviation of position, rotation, and calibration). The results are used to correct the measurement results obtained by using the second read head group, and the four read heads 60 1 to 60 are corrected accordingly. 4 The situation of the measurement error accompanied by the deviation between the regions on the scale plates 21 and 22 facing each other has been described, but it is not limited to this. For example, it can also be used for the position control of the wafer stage. Number) The plural (second) number of read heads moves the wafer stage in the area where position measurement can be performed separately to obtain the encoder. The correction system obtains location information of the stage, for example, can also move within the above-described embodiment of the cross area A 0 stage was used to obtain the correction information read head lengthy.
此場合,此修正資訊雖係係用於由主控制裝置20修正編碼器測量值之值,但不限於此,亦可於其他處理使用。 In this case, although the correction information is used to correct the value of the encoder measurement value by the main control device 20, it is not limited to this, and can also be used in other processes.
例如,亦可適用將該測量誤差作為偏移於晶圓載台之現在位置或目標位置加入偏移,以進行晶圓載台之驅動(位置控制)、或將標線片位置僅修正該測量誤差分等之其他手法。 For example, the measurement error can also be applied as an offset from the current position or target position of the wafer stage to drive the wafer stage (position control), or the position of the reticle can only correct the measurement error. And other methods.
又,上述實施形態中,雖係使用以第1及第2讀頭群所得之位置資訊 來求出與第1及第2讀頭群分別對應之第1及第2基準座標系C1、C2間之偏差(位置、旋轉、定標之偏差),但不限於此,曝光裝置亦可包含例如根據設於晶圓載台之複數個讀頭中、在對晶圓之曝光位置近旁於晶圓載台之外部配置成與XY平面略平行之複數個標尺板構成之測量面照射測量光束並接收來自測量面之返回光束之讀頭之輸出,以求出晶圓載台之位置資訊之位置測量系(例如編碼器系統),以及根據以該位置測量系取得之位置資訊驅動晶圓載台並視晶圓載台之位置從該複數個讀頭中切換該位置測量系用於取得該位置資訊之讀頭之控制系,該控制系在該複數個讀頭與該測量面對向之該移動體之第1移動區域內,取得與該複數個讀頭對應之複數個標尺板彼此之位置關係。此場合,可使複數個讀頭中、至少包含一個彼此互異之讀頭之複數個讀頭分別所屬之複數個讀頭群,分別與複數個標尺板對向。 In the above embodiment, the position information obtained from the first and second read head groups is used to obtain the first and second reference coordinate systems C 1 and C corresponding to the first and second read head groups, respectively. The difference between the two (position, rotation, and calibration), but is not limited to this. The exposure device may include, for example, a plurality of read heads provided on a wafer stage, and a wafer carrier near the exposure position of the wafer. The outside of the stage is arranged so that a measuring surface composed of a plurality of ruler plates that are slightly parallel to the XY plane irradiates the measuring beam and receives the output of the read head returning the beam from the measuring surface to obtain the position measurement system of the position information of the wafer stage ( (E.g. encoder system), and drive the wafer stage based on the position information obtained by the position measurement system and switch from the plurality of read heads according to the position of the wafer stage. The position measurement system is used to obtain the position information of the read head. A control system that obtains the positional relationship between the plurality of scale plates corresponding to the plurality of read heads in the first movement area of the plurality of read heads and the moving body facing the measurement face. In this case, among the plurality of read heads, the plurality of read head groups to which the plurality of read heads including at least one mutually different read head belong respectively may be opposed to the plurality of scale plates, respectively.
此場合,複數個標尺板彼此之位置關係,不僅可用於修正編碼器測量值之值,亦可於其他處理使用。例如,亦可適用將該測量誤差作為偏移於晶圓載台之現在位置或目標位置加入偏移,以進行晶圓載台之驅動(位置控制)、或將標線片位置僅修正該測量誤差分等之其他手法。 In this case, the positional relationship between the plurality of ruler plates can be used not only for correcting the value of the encoder measurement value, but also for other processes. For example, the measurement error can also be applied as an offset from the current position or target position of the wafer stage to drive the wafer stage (position control), or the position of the reticle can only correct the measurement error. And other methods.
又,上述實施形態,雖係針對各讀頭601~604(編碼器701~704)採用以XY平面內之一軸方向與Z軸方向為測量方向之二維編碼器之情形作了例示,但不限於此,亦可採用以XY平面內之1軸方向為測量方向之1維編碼器與以Z軸方向為測量方向之1維編碼器(或非編碼器方式之面位置感測器等)。或者,亦可採用以XY平面內彼此正交之之2軸方向為測量方向之二維編碼器。再者,亦可採用以X軸、Y軸及Z軸方向之3方向為測量方向之3維編碼器(3DOF感測器)。 In the above-mentioned embodiment, a case is described in which each of the read heads 60 1 to 60 4 (encoders 70 1 to 70 4 ) uses a two-dimensional encoder in which one axis direction in the XY plane and the Z axis direction are the measurement directions. Examples, but not limited to this, it is also possible to use a 1-dimensional encoder with the 1-axis direction in the XY plane as the measurement direction and a 1-dimensional encoder with the Z-axis direction as the measurement direction (or non-encoder face position sensing) Device, etc.). Alternatively, a two-dimensional encoder in which the two-axis directions orthogonal to each other in the XY plane are used as a measurement direction may be used. Furthermore, a three-dimensional encoder (3DOF sensor) in which the three directions of the X-axis, Y-axis, and Z-axis directions are used as measurement directions can also be used.
又,上述實施形態雖係針對曝光裝置為掃描步進機之情形作了說明,但不限於此,亦可於步進機等之靜止型曝光裝置適用上述實施形態。即使是步進機等,藉由以編碼器測量搭載有曝光對象物體之載台之位置,與使 用干涉儀測量載台位置之情形不同之,能使空氣波動造成之位置測量誤差之發生幾乎為零,可根據編碼器之測量值高精度的定位載台,其結果,能以高精度將標線片圖案轉印至晶圓上。此外,上述實施形態亦能適於將照射區域與照射區域加以合成之步進接合(step & stitch)方式之投影曝光裝置。再者,亦可於例如美國專利第6,590,634號說明書、美國專利第5,969,441號說明書、美國專利第6,208,407號說明書等所揭示之具備複數個晶圓載台之多載台型曝光裝置適用上述實施形態。此外,亦可於例如美國專利申請公開第2007/0211235號說明書及美國專利申請公開第2007/0127006號說明書等所揭示之具備與晶圓載台不同之、包含測量構件(例如基準標記及/或感測器等)之測量載台之曝光裝置適用上述實施形態。 In addition, although the above-mentioned embodiment has been described in the case where the exposure device is a scanning stepper, the embodiment is not limited to this, and the above-mentioned embodiment may be applied to a stationary exposure device such as a stepper. Even steppers and the like measure the position of the stage on which the exposure target The situation of using an interferometer to measure the position of the stage is different. It can make the position measurement error caused by air fluctuations almost zero. The stage can be positioned with high accuracy based on the encoder's measurement value. As a result, the standard can be calibrated with high accuracy The line pattern is transferred onto the wafer. In addition, the above-mentioned embodiment can also be adapted to a projection exposure device of a step & stitch method that combines the irradiation area and the irradiation area. Furthermore, the above-mentioned embodiment can also be applied to a multi-stage type exposure apparatus having a plurality of wafer stages disclosed in, for example, US Pat. No. 6,590,634, US Pat. No. 5,969,441, and US Pat. No. 6,208,407. In addition, it may be disclosed in, for example, U.S. Patent Application Publication No. 2007/0211235 and U.S. Patent Application Publication No. 2007/0127006 that are provided with a measurement member (such as a fiducial mark and / or sensor) that is different from a wafer stage. The above-mentioned embodiment is applicable to the exposure device of the measuring stage.
又,上述實施形態之曝光裝置,亦可以是例如國際公開第99/49504號、美國專利申請公開第2005/0259234號說明書等所揭示之液浸型曝光裝置。 The exposure apparatus of the above embodiment may be a liquid immersion exposure apparatus disclosed in, for example, International Publication No. 99/49504 and US Patent Application Publication No. 2005/0259234.
又,上述實施形態之曝光裝置中之投影光學系不限於縮小系而可以是等倍及放大系之任一種,投影光學系PL不限於折射系而亦可以是反射系及折反射系之任一種,其投影像可以是倒立像及正立像之任一種。 In addition, the projection optical system in the exposure apparatus of the above embodiment is not limited to the reduction system but may be any of the equal magnification and the magnification system, and the projection optical system PL is not limited to the refractive system and may be any of the reflection system and the refracting reflection system. The projection image can be either an inverted image or an upright image.
又,照明光IL不限於ArF準分子雷射光(波長193nm),亦可以是KrF準分子雷射光(波長248nm)等之紫外光、或F2雷射光(波長157nm)等之真空紫外光。亦可使用例如美國專利第7,023,610號說明書所揭示之以摻雜有鉺(或鉺及鐿兩者)之光纖放大器,將從DFB半導體雷射或光纖雷射發出之紅外線區或可見區的單一波長雷射光加以放大作為真空紫外光,並以非線形光學結晶將其轉換波長成紫外光之諧波。 The illumination light IL is not limited to ArF excimer laser light (wavelength 193 nm), but may be ultraviolet light such as KrF excimer laser light (wavelength 248 nm), or vacuum ultraviolet light such as F 2 laser light (wavelength 157 nm). It is also possible to use, for example, a single-wavelength infrared or visible region emitted from a DFB semiconductor laser or an optical fiber laser, using a fiber amplifier doped with erbium (or erbium and erbium), as disclosed in US Pat. No. 7,023,610. Laser light is amplified as vacuum ultraviolet light and converted into a harmonic of ultraviolet light by a non-linear optical crystal.
又,上述實施形態中,雖係使用在光透射性之基板上形成有既定遮光圖案(或相位圖案、減光圖案)之光透射型光罩(標線片),但亦可取代此標線片,使用例如美國專利第6,778,257號說明書所揭示之根據待曝光圖案之電 子資料,來形成透射圖案或反射圖案、或發光圖案之電子光罩(包含亦稱為可變成形光罩、主動光罩或影像產生器之例如非發光型影像顯示元件(空間光調變器)之一種的DMD(Digital Micro-mirror Device)等)。使用該可變成形光罩之場合,由於搭載晶圓或玻璃板片等之載台係相對可變成形光罩被掃描,藉由使用編碼器系統及雷射干涉儀系統測量此載台之位置,即能獲得與上述實施形態同等之效果。 In the above-mentioned embodiment, although a light-transmitting photomask (reticle) in which a predetermined light-shielding pattern (or phase pattern, or dimming pattern) is formed on a light-transmitting substrate is used, it is also possible to replace this graticule Sheet using, for example, the electric power according to the pattern to be exposed as disclosed in the specification of US Pat. No. 6,778,257 Sub-data to form a transmissive or reflective pattern, or a luminescent pattern of an electronic photomask (including a non-emissive image display element (spatial light modulator) ), Such as DMD (Digital Micro-mirror Device). When using this variable-shaped mask, the stage on which the wafer or glass plate is mounted is scanned relative to the variable-shaped mask, and the position of this stage is measured by using an encoder system and a laser interferometer system. That is, the same effect as that of the above embodiment can be obtained.
又,上述實施形態亦能適應用於例如國際公開第2001/035168號所揭示之藉由在晶圓W上形成干涉條紋,據以在晶圓W上形成線與空間圖案(line & space)圖案之曝光裝置(微影系統)。 In addition, the above-mentioned embodiment can also be applied to, for example, disclosed in International Publication No. 2001/035168 by forming interference fringes on the wafer W, thereby forming a line & space pattern on the wafer W. Exposure device (lithographic system).
再者,亦能將上述實施形態適用於例如美國專利第6,611,316號所揭示之將兩個標線片圖案透過投影光學系統合成在晶圓上,藉由一次掃描曝光使晶圓上之一個照射區域大致同時雙重曝光之曝光裝置。 Furthermore, the above-mentioned embodiment can also be applied to, for example, the synthesis of two reticle patterns on a wafer through a projection optical system as disclosed in US Patent No. 6,611,316, and one irradiation area on the wafer can be made by one scanning exposure. Exposure device for roughly simultaneous double exposure.
又,上述實施形態中待形成圖案之物體(被照射能量束之曝光對象物體)不限於晶圓,亦可以是玻璃板、陶瓷基板、薄膜構件或光罩母板等之其他物體。 In addition, the object to be patterned (the object to be exposed by the energy beam) in the above embodiment is not limited to a wafer, but may be other objects such as a glass plate, a ceramic substrate, a film member, or a photomask mother board.
曝光裝置之用途不限於半導體製造用之曝光裝置,亦能廣泛適用於例如將液晶顯示元件圖案轉印至方型玻璃板片之液晶用曝光裝置、及用以製造有機EL、薄膜磁頭、攝影元件(CCD等)、微機器及DNA晶片等之曝光裝置。此外,不僅僅是半導體元件等之微元件,本發明亦能適用於為製造光曝光裝置、EUV曝光裝置、X線曝光裝置及電子束曝光裝置等所使用之標線片或光罩,而將電路圖案轉印至玻璃基板或矽晶圓等之曝光裝置。 The application of the exposure device is not limited to that used for semiconductor manufacturing, but can also be widely applied to, for example, an exposure device for liquid crystal that transfers a pattern of a liquid crystal display element to a square glass plate, and an organic EL, a thin-film magnetic head, and a photographic element. (CCD, etc.), micromachines, and DNA wafers. In addition, not only micro-elements such as semiconductor elements, but the present invention can also be applied to reticle or photomask used for manufacturing light exposure device, EUV exposure device, X-ray exposure device and electron beam exposure device, etc. The circuit pattern is transferred to an exposure device such as a glass substrate or a silicon wafer.
又,援用以上說明所引用之關於曝光裝置等所有公報、國際公開公報、美國專利申請公開說明書及美國專利說明書之揭示作為本說明書記載之一部分。 In addition, the disclosures of all publications such as exposure devices, international publications, U.S. patent application publications, and U.S. patent specifications cited in the above description are cited as part of the description in this specification.
半導體元件等之電子元件,係經由進行元件之功能、性能設計之步驟、 製作依據此設計步驟之標線片之步驟、從矽材料製作晶圓之步驟、以前述各實施形態之曝光裝置(圖案形成裝置)及其曝光方法將光罩(標線片)圖案轉印至晶圓之微影步驟、使曝光後晶圓(物體)顯影之顯影步驟、將殘存有光阻之以外部分之露出構件以蝕刻加以去除之蝕刻步驟、將蝕刻後不要之光阻去除之光阻除去步驟、元件組裝步驟(包含切割步驟、結合步驟、封裝步驟)、以及檢査步驟等而製造出。此場合,於微影製程使用上述實施形態之曝光裝置及曝光方法,因此能以良好之生產性製造高積體度之元件。 Electronic components such as semiconductor devices are designed by the steps of designing the function and performance of the device. The step of making a reticle according to this design step, the step of making a wafer from a silicon material, and using the exposure apparatus (pattern forming apparatus) and the exposure method of the foregoing embodiments to transfer the photomask (reticle) pattern to Photolithography step of wafer, development step of developing wafer (object) after exposure, etching step of removing exposed members remaining outside the photoresist by etching, photoresist of removing unnecessary photoresist after etching It is manufactured by a removal step, a component assembly step (including a dicing step, a bonding step, a packaging step), and an inspection step. In this case, since the exposure apparatus and exposure method of the above-mentioned embodiment are used in the lithography process, a high-integration component can be manufactured with good productivity.
如以上所述,上述實施形態之曝光裝置(圖案形成裝置),係將包含本案申請專利範圍所舉之各構成要素的各種子系統,以能保持既定機械精度、電氣精度、光學精度之方式,加以組裝製造。為確保上述各種精度,於此組裝之前後,對各種光學系統進行用以達成光學精度之調整,對各種機械系統進行用以達成機械精度之調整,對各種電氣系統則進行用達成各種電氣精度之調整。各種子系統組裝至曝光裝置之步驟,包含各種子系統彼此間之機械連接、電氣迴路之連接、氣壓迴路之連接等。此各種子系統組裝至曝光裝置之步驟前,當然有各個子系統之組裝步驟。各種子系統組裝至曝光裝置之步驟結束後,即進行綜合調整,以確保曝光裝置全體之各種精度。又,曝光裝置的製造以在溫度及清潔度等受到管理的無塵室中進行較佳。 As described above, the exposure device (pattern forming device) of the above embodiment will include various subsystems including the constituent elements listed in the scope of the patent application for this application, in a manner capable of maintaining predetermined mechanical, electrical, and optical accuracy. Assembled and manufactured. In order to ensure the above-mentioned various precisions, before and after this assembly, various optical systems are adjusted to achieve optical accuracy, various mechanical systems are adjusted to achieve mechanical accuracy, and various electrical systems are used to achieve various electrical accuracy. Adjustment. The steps of assembling various subsystems to the exposure device include mechanical connections between various subsystems, electrical circuit connections, and pneumatic circuit connections. Before the steps of assembling the various subsystems to the exposure device, there are of course the steps of assembling the various subsystems. After the steps of assembling various subsystems to the exposure device are completed, comprehensive adjustment is performed to ensure various accuracy of the entire exposure device. In addition, the exposure device is preferably manufactured in a clean room in which temperature, cleanliness, and the like are managed.
[產業上之可利用性] [Industrial availability]
如以上之說明,本發明之曝光方法及曝光裝置適於使物體曝光。又,本發明之元件製造方法非常適於製造半導體元件或液晶顯示元件等之電子元件。 As explained above, the exposure method and exposure device of the present invention are suitable for exposing objects. The device manufacturing method of the present invention is very suitable for manufacturing electronic devices such as semiconductor devices and liquid crystal display devices.
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